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R E V I E W A R T I C L EThe mystery of nonclassical protein secretion A current view on cargo proteins and potential export routes Walter Nickel Biochemie-Zentrum Heidelberg, University

R E V I E W A R T I C L E

The mystery of nonclassical protein secretion

A current view on cargo proteins and potential export routes

Walter Nickel

Biochemie-Zentrum Heidelberg, University of Heidelberg, Germany

Most of the examples of protein translocation across a

membrane (such as the import of classical secretory proteins

into the endoplasmic reticulum, import of proteins into

mitochondria and peroxisomes, as well as protein import

into and export from the nucleus), are understood in great

detail In striking contrast, the phenomenon of

unconven-tional protein secretion (also known as nonclassical protein

export or ER/Golgi-independent protein secretion) from

eukaryotic cells was discovered more than 10 years ago and

yet the molecular mechanism and the molecular identity of

machinery components that mediate this process remain

elusive This problem appears to be even more complex as

several lines of evidence indicate that various kinds of

mechanistically distinct nonclassical export routes may exist

In most cases these secretory mechanisms are gated in a

tightly controlled fashion This reviewaims to provide a

comprehensive overviewof our current knowledge as a basis

for the development of newexperimental strategies designed

to unravel the molecular machineries mediating ER/Golgi-independent protein secretion Beyond solving a funda-mental problem in current cell biology, the molecular analysis of these processes is of major biomedical importance

as these export routes are taken by proteins such as angio-genic growth factors, inflammatory cytokines, components

of the extracellular matrix which regulate cell differentiation, proliferation and apoptosis, viral proteins, and parasite surface proteins potentially involved in host infection Keywords: unconventional protein secretion; nonclassical export; protein targeting; membrane translocation; extra-cellular localization; FGF-2 trafficking; galectin trafficking; Leishmania HASPB trafficking; interleukin 1a and 1b trafficking; ER/Golgi-independent protein secretion

Introduction

Soluble secretory proteins typically contain N-terminal

signal peptides that direct them to the translocation

apparatus of the endoplasmic reticulum (ER) [1] Following

vesicular transport from the ER via the Golgi to the cell

surface, lumenal proteins are released into the extracellular

space by fusion of Golgi-derived secretory vesicles with the

plasma membrane [2–5] This pathway of protein export

from eukaryotic cells is known as the classical or

ER/Golgi-dependent secretory pathway However, more than 10 years

ago, it was reported that interleukin 1b (IL1b) and galectin-1

(also referred to as L-14) could be exported from cells in the

absence of a functional ER/Golgi system [6,7] Since then,

the list of proteins demonstrated to be secreted by

uncon-ventional means is steadily growing Figure 1 gives an

overviewof cellular, viral and parasitic proteins that have

been shown to be exported by mechanisms that are

operational in the absence of a functional ER/Golgi system

The basic observations (summarized previously in [8,9]) that

led to the proposal of alternative pathways of eukaryotic

protein secretion are (a) the lack of conventional signal peptides in the secretory proteins in question, (b) the exclusion of these proteins from classical secretory organel-les such as the ER and the Golgi combined with the lack of ER/Golgi-dependent post-translational modifications such

as N-glycosylation and (c) resistance of these export processes to brefeldin A, a classical inhibitor of ER/Golgi-dependent protein secretion [10–12] Because the secretory proteins discussed here are soluble factors synthesized on free ribosomes in the cytoplasm, various experimental strategies have been pursued in order to exclude unspecific release based on cell death under the experimental condi-tions applied As described in detail in the following sections, these experiments included parallel quantitative measurements of the appearance of unrelated cytoplasmic proteins in cellular supernatants [8,9] as well as the identification of mutants that are deficient in nonclassical export [13] Moreover, nonconventional protein secretion was shown to be dependent on both energy and temperature and is stimulated or inhibited by various treatments [8,9] Finally, nonconventional protein secretion processes were shown to be regulated for example by cell differentiation [7,14], NF-jB-dependent signalling pathways [15], and post-translational modifications such as phosphorylation [16] Based on these observations, it has to be concluded that the secretory proteins discussed in this reviewexit eukaryotic cells in a controlled manner mediated by proteinaceous machineries In the following sections, the various cargo proteins known to be secreted by unconventional means will

be discussed in detail

Correspondence to W Nickel, Biochemie-Zentrum Heidelberg,

University of Heidelberg, Im Neuenheimer Feld 328,

69120 Heidelberg, Germany.

E-mail: walter.nickel@urz.uni-heidelberg.de

Abbreviations: ER, endoplasmic reticulum; FGF, fibroblast

growth factor.

(Received 12 February 2003, accepted 17 March 2003)

Cytokines: interleukin-1b, thioredoxin

and macrophage migration inhibitory factor

In 1987, Dinarello and colleagues demonstrated that

interleukin 1, a cytokine [17,18] lacking a classical signal

peptide for ER/Golgi-mediated protein secretion [19], is

exported from activated human monocytes [20] Two

isoforms of interleukin 1 termed IL-1a and IL-1b have

been described which represent proteolytically processed

forms derived from two related but distinct precursors [18]

The processing of IL-1a involves myristoylation and,

following insertion into the plasma membrane,

calpain-dependent cleavage that is thought to cause release of the

mature form of IL-1a into the extracellular space [21,22] In

the case of IL-1b, interleukin-converting enzyme produces

mature IL-1b [23,24], which is then exported [18]

Most studies targeted toward the molecular mechanism

of interleukin 1 export have been focused on the b-isoform

A detailed molecular analysis of the export process revealed

that IL-1b does not make use of an unconventional

pathway of translocation into the lumen of the endoplasmic

reticulum but rather appears to utilize a secretory

mechan-ism independent of ER/Golgi-related vesicular transport [6]

This process was shown to be distinct from unspecific

release as for example only the processed form of IL-1b

(17 kDa) can be detected in cellular supernatants whereas

the precursor (33 kDa) is retained by IL-1b-expressing cells

[6] Moreover, under the experimental conditions applied,

only the b-isoform was found to be secreted, whereas the

a-isoform could not be detected in cellular supernatants

[6] However, despite apparently utilizing a distinct secretory

mechanism, it was later found that IL-1a is also exported [21]

Though IL-1b is found in certain intracellular vesicles, as judged by protease protection experiments, these structures appear to be unrelated to the ER/Golgi system as IL-1b secretion was not inhibited but rather stimulated by brefeldin A, a drug that compromises the structure and function of the Golgi apparatus [10–12] Consistently, IL-1b was found not to be glycosylated, despite bearing corres-ponding consensus sequences Intracellular vesicles pro-posed to play a role in IL-1b secretion have been shown to

be related to an endolysosomal compartment that releases its content upon fusion with the plasma membrane [25] These observations are consistent with the fact that IL-1b secretion is sensitive to methylamine [6], a drug that disturbs endocytosis [26] Based on pharmacological studies employing the sulfonylurea glyburide (10 lM) along with expression-inhibition studies employing antisense tech-niques, an ABC transporter, ABC1, has been implicated

in the overall process of IL-1b secretion [27,28] and therefore might mediate IL-1b translocation from the cytoplasm to the lumen of the endolysosomal compartment Interestingly, glyburide also appears to inhibit nonclassi-cal secretion of macrophage migration inhibitory factor (J Bernhagen, RWTH Aachen, Germany, personal com-munication), an inflammatory cytokine mediating a number

of immune and inflammatory diseases, e.g bacterial septic shock [29–31] The potential function of ABC transporters

in these processes might be related to that of bacterial ABC transporters that mediate protein secretion of, for example, hemolysin [32–34]

Fig 1 Cargo proteins and potential export routes of unconventional protein secretion At least four distinct types of nonclassical export can be distinguished For IL-1b, En2 and HMGB1, export involves import into intra-cellular vesicles, which are probably endo-somal subcompartments FGF-1 and FGF-2 probably reach the extracellular space by direct translocation across the plasma mem-brane, but they apparently use distinct trans-port systems The Leishmania cell surface protein HASPB also translocates directly across the plasma membrane and requires that the protein is membrane-anchored through dual acylation at the N-terminus Therefore, a flip-flop mechanism is required to locate the protein in the outer leaflet of the plasma membrane The final postulated pathway of unconventional protein secretion involves the formation of exosomes, vesicles that form on the outer surface of the cell in a process known

as membrane blebbing Exosomes are labile structures that release their contents into the extracellular space It has been suggested that this pathway may be used by the galectins.

Thioredoxins are ubiquitous intracellular enzymes that

catalyze thiol-disulfide exchange reactions [35] Additionally,

extracellular populations of thioredoxin have been detected

that, similar to IL-1b and migration inhibiting factor, follow

an ER/Golgi-independent route of secretion [36–39] This

observation is consistent with additional physiological roles

of thioredoxin such as its function as a mitogenic cytokine

that requires extracellular localization [40,41] Secretion of

thioredoxin appears to be mediated by a pathway distinct

from IL-1b as it could neither be detected in intracellular

vesicles, nor was the secretion process reported to be

inhibited by reagents that interfere with the function of

ABC transporters However, as with IL-1b [6], secretion of

thioredoxin is inhibited by methylamine and stimulated by

brefeldin A [39] Interestingly, the redox state of thioredoxin

does not influence its unconventional export [42]

Pro-angiogenic growth factors:

FGF-1 and FGF-2

Fibroblast growth factor 1 and 2 (FGF-1 and FGF-2) belong

to a large family of heparin-binding growth factors [43] that,

apart from their mitogenic activity [43,44], are key activators

of tumor-induced angiogenesis [45] The majority of the

members of the FGF family are exported by

ER/Golgi-dependent secretory transport However, FGF-1 and the

18 kDa isoform of FGF-2 have been shown to be secreted by

an alternative pathway [46–48] While it was first assumed

that angiogenic growth factors might be released from

mechanically injured tissue to promote wound healing [49], a

process that requires angiogenesis, various lines of evidence

demonstrate that FGF-1 and FGF-2 are exported from

cultured cells in the absence of appreciable amounts of cell

death [46–48,50,51] Like IL-1b [6], FGF-1 is increasingly

secreted under stress conditions such as heat shock treatment

[46,52] In contrast, FGF-2 export is not affected under these

experimental conditions [53] While serum starvation has

been reported to inhibit export of both FGF-2 [48] and IL-1b

[6], it was found to actually induce secretion of FGF-1 [52]

Similarly, methylamine has been found to block export only

of 2 [48] and IL-1b [6] with no apparent effect on

FGF-1 export [54] Recently, it was reported that expression of the

IL-1a precursor inhibits FGF-1 release in response to

temperature stress [55] In contrast, expression of the mature

form of IL-1a did not affect FGF-1 export, suggesting that

IL-1a processing is somehowrelated to FGF-1 biogenesis

However, whether FGF-1 and IL-1a utilize similar export

mechanisms remains an open question

These observations point to some common characteristics

in the export of the cargo proteins discussed, but it seems

unlikely that one and the same machinery mediates secretion

of these factors Consistent with this view, IL-1b has been

reported to be secreted by a vesicular nonclassical export

pathway [6,25], while FGF-1 and FGF-2 are likely to be

directly translocated from the cytoplasm into the

extracel-lular space (Fig 1) While there is also one report pointing to

a role of large granules involved in FGF-2 export based on

immuno-EM analysis of mast cells [56], this issue remains

controversial as intracellular FGF-2 has been localized to the

cytoplasm in many FGF-2-secreting cell types with no

apparent localization in vesicular structures [50,57–59]

Similar findings have been reported for FGF-1 [60–62]

With regard to the protein components involved in the overall processes of nonclassical export pathways, most is known about the secretion of FGF-1 As noted above, FGF-1 export is significantly increased in response to stress conditions such as heat shock treatment [46] and serum starvation [52] Based on these experimental conditions, it was shown that secreted FGF-1 isolated from cell culture supernatants represents a latent (inactive form that can be reactivated) homodimer [54] that can also be formed upon chemical oxidation of FGF-1 in vitro [63] These observa-tions led to the discovery of a specific cysteine residue (Cys30) in FGF-1 that is required for both dimer formation and nonclassical export of FGF-1 [13,54] Upon heat shock treatment, two intracellular proteins have been shown to associate with the latent FGF-1 homodimer in the cyto-plasm These are a cleavage product of the transmembrane protein synaptotagmin consisting of its cytoplasmic domain (p40-Syt1) and the Ca2+-binding protein S100A13 Appar-ently, they are exported together with FGF-1 [64–66] A direct role of p40-Syt1 and S100A13 in FGF-1 export has been proposed as both repression of p40-Syt1 expression by antisense techniques and the expression of a dominant-negative S100A13 mutant attenuate FGF-1 export [64,66]

As with FGF-1 dimer formation [63], oxidation by Cu2+ cations has been demonstrated to trigger the formation of a complex consisting of FGF-1, p40-Syt1 and S100A13 [67] Consistent with the view that p40-Syt1 and S100A13 are involved in the export of FGF-1, tetrathiomolybdate, a

Cu2+ chelator, has been shown to inhibit heat shock-induced FGF-1 export [67] More recently, stress-shock-induced formation of the intracellular FGF-1–p40-Syt1–S100A13 complex has been demonstrated to cause a redistribution of cytoplasmic FGF-1 to the inner surface of the plasma membrane [62] These results suggest that FGF-1–p40-Syt1–S100A13 complex formation is the first step in the FGF-1 export pathway, followed by direct translocation of this protein complex across the plasma membrane How-ever, the machinery that mediates membrane translocation

of this protein complex remains unknown

Compared to FGF-1 export, much less is known about the mechanism and the role of specific proteins with regard

to the overall process of FGF-2 export from mammalian cells To date the only protein that has been proposed to play a role in FGF-2 export is the Na+/K+-ATPase [68] This conclusion was based initially on the observation that cardiac glycosides such as ouabain partially inhibit FGF-2 export [50,68,69] This was further strengthened by experi-ments demonstrating that the expression of an ouabain-resistent a-subunit mutant of the Na+/K+-ATPase rescues FGF-2 export in the presence of ouabain [70] Moreover, a direct or indirect physical interaction between the a subunit and FGF-2 has been detected based on coimmunopreci-pitation though this association could only be observed upon co-overexpression of both proteins [68] Together with the result that overexpression of the a subunit interferes with FGF-2 export [68], these observations are reasonably supportive of a role for the Na-K-ATPase in the overall process of FGF-2 export On the other hand, ouabain treatment (typically used at 10–100 lM) causes only partial inhibition of FGF-2 export, whereas concentrations of ouabain of less than 5 lM(IC50 1 lM) completely inhibit the ATP-dependent translocation of cations catalyzed by

the Na+/K+-ATPase [71,72] Interestingly, the membrane

potential generated by the Na+/K+-ATPase is not required

for FGF-2 export [68] Based on these observations, it has

been proposed that the a/b heterodimers that constitute a

functional Na+/K+-ATPase in terms of ion transport

might be able to form higher ordered complexes that

catalyze FGF-2 export in a membrane

potential-independ-ent manner [68] Alternatively, the a subunit alone might

associate with other so far uncharacterized factors as part of

a novel complex that mediates FGF-2 export [68]

Unfor-tunately, no progress has yet been made in identifying such

molecular structures

Galectins: components of the extracellular

matrix

The members of the galectin protein family are abundant

b-galactoside-specific lectins of the extracellular matrix

implicated in many cellular processes such as regulation of

cell proliferation, differentiation and apoptosis [73–76] The

best characterized members of this family are galectin-1 and

galectin-3 which are present as soluble proteins in the

cytoplasm in a wide range of vertebrate cell lines and tissues

[7,14,77–81] Secreted galectins are found either bound to the

extracellular surface of the plasma membrane or as abundant

components of the extracellular matrix [7,14,77,79–81] Cell

surface association of galectins is mediated by both N- and

O-glycosylated b-galactose-terminated oligosaccharide side

chains of glycoproteins [9,73] as well as by

galactose-containing glycolipids such as GM1[73,82] As galectin-1

and galectin-3 can form homodimers [9,83,84], it has been

proposed that secreted galectins affect their glycosylated

cell-surface counter receptors by inducing conformational

chan-ges of their extracellular domains and/or by clustering

galectin counter receptors based on noncovalent crosslinking

of oligosaccharide moieties [73] In this way, secreted

galectins are thought to affect processes such as cell

differentiation by cell surface counter receptor-mediated

signalling [73,85] While classical counter receptors of, for

example, galectin-1 include laminin [86], fibronectin [87] and

cell-type specific receptors such as T cell CD43 and CD45

[75], it has been shown more recently that the tumor-specific

cell surface antigen CA125 also represents a galectin counter

receptor that preferentially binds galectin-1 [79] This latter

example is of particular interest as it provides a potential

molecular mechanism for howtumor cells can differentially

interact with the extracellular matrix, a process crucial for

tumor progression

Similar to interleukin 1b, FGF-1 and FGF-2, galectins

apparently do not contain signal peptides in their primary

structure suitable for ER/Golgi-mediated secretion [88]

Consistently, galectins are synthesized on free ribosomes in

the cytoplasm [89] and galectin secretion has been shown

not to be blocked by inhibitors of the ER/Golgi-dependent

pathway such as brefeldin A and monensin [9,80,90] Unlike

interleukin 1b, galectin-1 and galectin-3 do not appear to be

packaged into intracellular vesicles prior to export

[7,9,80,81] Rather, galectin-1 and galectin-3 have been

shown to accumulate directly below the plasma membrane,

followed by an export mechanism that appears to involve

the formation of membrane-bound vesicles (also called

exosomes but not to be confused with structures involved in

RNA processing [91]) that pinch off before being released into the extracellular space [7,9,80,81] This mechanism also distinguishes galectin export from FGF-1 and FGF-2 export, as there is no evidence that these proteins are packaged into exosomes (see above) An engineered version

of galectin-3 containing an N-terminal acylation motif derived from a protein tyrosine kinase (p56lck) has been show n to be secreted more efficiently than w ild-type galectin-3 [81] These results indicate that targeting to the plasma membrane is a rate-limiting step in galectin secre-tion However, there is no information describing exactly what causes galectin-1 and galectin-3 to accumulate at specific spots underneath the plasma membrane, and what actually causes the formation of exosomes into which these proteins appear to be packaged in an active fashion

Other secretory proteins exported

by nonconventional means

HIV-Tat, Herpes simplex VP22 and foamy virus Bet Besides the classical examples of ER/Golgi-independent protein secretion described above, a whole variety of proteins has been reported to be secreted by nonconven-tional means Among them are many factors whose localization-dependent functions, akin to those noted above, are of tremendous biomedical importance Such proteins include virus-encoded factors that are critical for the viral replication cycle The most prominent example is HIV-Tat, one of the auxiliary proteins required by HIV in addition to structural and enzymatic proteins to replicate its genome [92] HIV-Tat has been shown to be released from both HIV-infected and HIV-Tat-transfected cells in the absence of appreciable amounts of cell death [93,94] Intriguingly, HIV-Tat contains a region in its primary structure termed the basic transduction domain that appears to enable the protein to traverse membranes [95,96] The molecular mechanism of this translocation process does not seem to involve a proteinaceous machinery

as another HIV-Tat-like protein transduction domain, the antennapedia third helix domain [96], has been shown to cross artificial protein-free membranes [97] Another unusual feature of protein transduction domains is their apparent ability to translocate across membranes even at

4°C [96,98], an observation consistent with a membrane translocation mechanism independent of proteinaceous machinery In all cases, however, protein transduction domains appear to function in unconventional modes of protein uptake by mammalian cells Specifically, in the cases

of HIV-Tat and Herpes simplex tegument protein VP22, it

is rather unlikely that their ER/Golgi-independent export mechanisms are based on their protein transduction domains For example, HIV-Tat secretion from cultured cells is a temperature-dependent process [94] Thus, protein transduction-dependent uptake and ER/Golgi-independent export of protein transduction domain-containing factors might be mechanistically distinct processes Similar to herpes simplex VP22, a secreted auxiliary protein termed Bet encoded by foamy viruses [99] has been shown to spread between cultured cells [100] Interestingly, both VP22 and Bet are found in the cytoplasm of expressing cells whereas they are targeted to the nucleus of cells that received the

protein by intercellular spreading [98,100] In both cases,

this process is not affected by brefeldin A, suggesting that

export of VP22 and Bet from expressing cells does not

involve the ER/Golgi system [98,100] In conclusion, it

appears likely that uptake by mammalian cells of HIV-Tat,

VP22 and possibly Bet is mediated by transduction domains

in a temperature-insensitive manner whereas export is

mediated in a temperature-sensitive manner by

proteina-ceous machineries that are insensitive to brefeldin A

Leishmania HASPB

Another quite remarkable example of nonclassical protein

export from eukaryotic cells is the mechanism of cell surface

expression of Leishmania HASPB (hydrophilic acylated

surface protein B) which is found associated with the outer

leaflet of the plasma membrane only in the infectious stages

of the parasite lifecycle [101,102] The protein is synthesized

on free ribosomes in the cytoplasm and becomes both

myristoylated and palmitoylated at its N-terminus, which

is the molecular basis of howHASPB is anchored in the

membrane [103] Mutational analysis revealed that an

HASPB construct lacking its 18 N-terminal amino acids is

redistributed into the cytoplasm [103] The same is true for a

mutant that retains the N-terminus but lacks the

myristoy-lation site [103] Interestingly, a mutant that lacks the

palmitoylation site but continues to be myristoylated has

been found associated with the cytoplasmic surface of the

Golgi apparatus [103] Based on these observations, a model

has been proposed in which HASPB is transferred from the

cytoplasm to the outer leaflet of the Golgi membrane, from

where it is transported to the plasma membrane via

conventional vesicular transport This process would insert

HASPB into the inner leaflet of the plasma membrane At

present it is completely unclear howHASPB is then

translocated across the membrane, resulting in the insertion

of the two acyl chains in the outer leaflet of the plasma

membrane Intriguingly, heterologous expression of various

HASPB fusion proteins in mammalian cells revealed the

existence of a machinery that is capable of translocating the

protein across the plasma membrane [103], demonstrating a

conserved pathway among lower and higher eukaryotes No

endogenous mammalian cargo proteins that make use of

this type of export system have been identified

Homeodomain-containing transcription factors

and HMG (high mobility group) chromatin-binding

proteins

As another example of nonclassical protein export, two

classes of proteins involved in the overall process of

regulated gene transcription have been proposed to operate

as extracellular factors even though they are normally

localized to the nucleus of mammalian cells [104–106] For

the transcription factor Engrailed homeoprotein isoform 2

(En2), a potential paracrine signalling activity was

postula-ted as a subpopulation of En2 has been localized to the cell

periphery in caveolae-like structures [105] In addition, a

small but significant portion of total cellular En2 was found

to reside in membrane-bound vesicles as judged by protease

protection experiments [105] Therefore, it was reasoned

that En2, despite lacking a conventional ER signal peptide,

might be secreted at a certain rate This hypothesis was tested experimentally by coculturing COS cells expressing the chicken orthologue of En2 (cEn2) with rat primary neurons demonstrating intercellular transfer of cEn2 [106] Interestingly, not only export from COS cells but also import by cocultured primary neurons appears to rely on nonclassical mechanisms, as cellular uptake of cEn2 was shown to depend on an unusual WF motif in position 48–49 [106] This sequence is also required for the uptake of other homeodomain-containing proteins [107–109] The internali-zation of homeodomain-containing proteins apparently differs from classical endocytosis, as it seems to occur by direct translocation across the plasma membrane [106] This process might be similar to the uptake mechanism of some viral proteins such as HIV-Tat and Herpes simplex VP22 as discussed above [108]

About 5% of total cellular En2 becomes externalized by COS cells which is about the portion that is also found to be protected against protease treatment An 11-amino acid sequence within the homeodomain of En2 has been identified that, when removed, causes a block in export of the corresponding mutant protein [106] This phenotype corre-lates with the disappearance of the mutant protein from the protease-protecting organelle, which probably represents a kind of a secretory compartment [106] The homeodomain-derived peptide was later shown to be part of a nuclear export signal and therefore promotes retrotranslocation of En2 from the nucleus into the cytoplasm [110] These results have been taken to mean that retrotranslocation of En2 from the nucleus to the cytoplasm is a prerequisite for nonclassical export of En2 [110] While the homeodomain-derived peptide was originally thought to represent a signal for nonclassical export, this viewhas to be re-evaluated as it might only trigger cytoplasmic localization of En2 and may not be required afterwards for externalization of En2 HMG proteins are intranuclear factors that mediate the assembly of site-specific DNA-binding proteins within chromatin [111] As a surprising finding, but similar to the homeodomain-containing transcription factors described above, HMGB1 is secreted during certain physiological processes such as inflammation Specifically, monocytes have been shown to export HMGB1 upon stimulation with bacterial lipopolysaccharides [112] Because antibodies against HMGB1 suppress LPS-induced endotoxemia, and injection of HMGB1 protein into mice causes toxic shock, HMGB1 apparently acts as a mediator of endotoxin lethality

in mice [112] Interestingly, HMGB1 export competence appears to be a special property of a limited number of cell types (such as monocytes and macrophages) as many cell types including lymphocytes are not capable of secreting HMGB1 [112] Again, similar to homeodomain-containing transcription factors, extracellular HMGB1 has also been shown to act as both an autocrine and paracrine signalling molecule promoting differentiation processes of the HMGB1-secreting cell [113,114] or other cells nearby [115]

As with all the examples of unconventional protein secretion discussed in this review, HMGB1 does not contain

a signal peptide for translocation into the ER [104] Similar

to IL-1b, FGF-2 and galectin-3 [9], a rise in intracellular

Ca2+ triggers HMGB1 export [114,115] Akin to the mobilization of homeodomain-containing transcription factors, HMGB1 has been observed to redistribute from

the nucleus to the cytoplasm upon activation of monocytes

[116] A detailed ultrastructural analysis revealed that

redistributed HMGB1 localizes to an endolysosomal

compartment from which secretion can be triggered by

stimuli known to promote lysosomal exocytosis [116] These

characteristics are strikingly similar to the process of IL-1b

secretion [25] However, IL-1b secretion from monocytes

can be triggered by adding exogenous ATP, whereas

HMGB1 release is induced by lysophosphatidylcholine

Moreover, the kinetics of IL-1b and HMGB1 release from

monocytes differ significantly, with IL-1b being secreted

early after monocyte activation and HMGB1 at a later

stage IL-1b consistently acts at an early phase of

inflam-mation whereas HMGB1 functions as a late mediator of

inflammation (see above) These results have been taken to

indicate that lysosomal exocytosis might involve distinct

populations of endolysosomal vesicles, thereby allowing

different kinetics of cargo release [116]

Direct translocation of proteins from the cytoplasm into

the lumen of lysosomes has been reported [117] but this

pathway appears to function primarily for enhanced

degradation of these proteins [118] The corresponding

targeting motif KFERQ [118] is not found in the primary

structure of IL-1b, En2 or HMGB1 It therefore appears

more likely that these factors are translocated by a different

mechanism A potential candidate is ABC1, an ABC

transporter that has been implicated to play a role in the

overall process of IL-1b secretion [27,28]

Cytoplasmic clearance of unfolded proteins

by nonclassical secretion

The mitochondrial matrix protein rhodanese, a monomeric

sulfotransferase, that, following synthesis on free ribosomes

in the cytoplasm, is normally imported into mitochondria,

represents another unusual example of nonclassical protein

export from mammalian cells When overexpressed in

HEK-293 cells from a strong viral promotor, about 40% of

total rhodanese was found to be secreted into the culture

medium [119] Export was shown to occur in the absence of

appreciable amounts of cell death and to depend on neither

the mitochondrial targeting sequence of rhodanese nor a

functional ER/Golgi system [119] Based on the observation

that rhodanese acquires its enzymatic activity only after

import into the mitochondrial matrix (and that the signal

peptide cannot be an inhibitor of enzymatic activity as it is

not cleaved off in the matrix), it was concluded that the

population present in the cytoplasm remains unfolded

before import into mitochondria Therefore, it has been

postulated that the export pathway detected for rhodanese

represents a mechanism for clearing the cytoplasm of

unfolded proteins that apparently accumulate upon

over-expression [119] More recently, a potentially similar

example of cytoplasmic clearance of an unfolded protein

population possibly generated by overexpression has been

observed [120] In this case, an unfolded subpopulation of

transiently overexpressed GFP was found to be secreted in a

brefeldin A-insensitive manner This effect has not been

observed in stable cell lines that express moderate levels of

GFP in a doxicycline-dependent manner [50] However,

these different observations are not necessarily inconsistent

as in the latter case an unfolded population of GFP is

unlikely to exist Interestingly, methylamine and other drugs known to inhibit nonclassical export of substrates such as IL-1b, FGF-2, thioredoxin, and the galectins ([9]; see above)

do not block externalization of rhodanese or unfolded GFP [119,120], again suggesting the existence of distinct mole-cular mechanisms of unconventional protein secretion

Targeting motifs and regulation

of nonclassical protein export

In many cases of intracellular protein sorting, short, linear amino acid sequences have been identified that serve as sorting motifs, including N-terminal signal peptides for ER translocation and the N-terminal targeting signals of mitochondrial proteins [118,121] Currently, very limited information is available about motifs directing proteins to the various pathways of unconventional protein secretion described above The most defined one is that of Leishmania HASPB which consists of a linear sequence of 18 amino acids at the extreme N-terminus referred to as HASPB-N18 [103] This sequence is both necessary and sufficient to direct

a corresponding fusion protein to the HASPB export pathway in both parasites and mammalian cells HASPB-N18 is myristoylated at a glycine residue in position 2 and palmitoylated at a cysteine residue in position 5 HASPB externalization requires that both residues are acylated However, a construct termed HASPB-N10, which contains both acylation sites but lacks the amino acids 11–18, fails to translocate across the plasma membrane [103] These results suggest that acylation might only be required to initially insert the protein into the membrane, and the translocation that follows requires an interaction of the proteinaceous part of HASPB-N18 with the putative export machinery Based on these characteristics, the HASPB export pathway appears to be unrelated to other examples of nonclassical protein export described here As the pathway is functional

in mammalian cells, endogenous substrates are likely to exist However, the 18-amino acid sequence found at the N-terminus of HASPB is not only absent from other secretory proteins exported by unconventional means but is also not found in any mammalian protein

Akin to Leishmania HASPB, the N-terminus of galectin-3 has been proposed to contain targeting information for nonclassical export [122,123] When the first 120 amino acids of galectin-3 are deleted, the residual portion of the protein is no longer secreted Conversely, addition of this N-terminal segment to a cytosolic protein directs the corresponding fusion protein to the galectin-3 export pathway A short sequence comprising residues 89–96 (based on the hamster amino acid sequence) was identified that, upon deletion, causes a breakdown of galectin-3 export However, the addition of this small peptide to a cytosolic protein is not sufficient to direct the resulting fusion protein to the galectin-3 export pathway suggesting that, besides the critical role of this short segment, other determinants for nonclassical export exist in the N-terminal part of galectin-3 [123] When compared to the galectin-1 amino acid sequence, no significant homologies can be found within the N-terminal 120 amino acids of galectin-3

In contrast to HASPB and galectin-3, the C-terminal half

of FGF-1 has been implicated in its temperature stress-induced release [124] A domain comprising a stretch of

amino acids from position 83–154 (based on the human

FGF-1 orthologue) appears to prevent the protein from

entering the nucleus, which has been suggested to be a

prerequisite for unconventional export When the

corres-ponding domain of FGF-2 was transferred to FGF-1,

secretion of the resulting hybrid protein was no longer

observed These data have been taken to mean that FGF-1

and FGF-2 are exported by distinct pathways [124], which is

consistent with the observation that only FGF-1 release can

be triggered by temperature stress [46,54] The actual

targeting motifs for nonclassical export have not been

revealed for either FGF-1 or FGF-2

For the homeodomain-containing transcription factor

En2, it has been suggested that an 11-amino acid motif

within the homeodomain may function as a signal for

nonclassical export [106] As discussed above, this

sequence was later found to be part of a nuclear export

signal suggesting that nuclear export of En2 is a

prerequisite for its unconventional secretion [110]

There-fore, it is rather unlikely that this signal is required for the

export process of En2 Interestingly, En2 has been shown

to be a substrate for protein kinase CK2 which, upon

phosphorylation of En2 within a serine-rich domain,

causes attenuation of En2 secretion [16] At this point, it is

not clear whether this segment of En2 (residues 146–169)

is part of a signal sequence for nonclassical export or

whether this domain regulates access of En2 to its export

pathway In either case, the information for En2 export

must lie within the En2 homeodomain, as this part of the

protein alone is an efficient substrate for intercellular

transfer [16] Phosphorylation-dependent regulation might

be a general principle for the regulation of intercellular

transfer, at least for a subset of these cargo proteins, as it

has also been suggested to play a role in the intercellular

transfer of VP22 [125,126]

Similar to En2 export, many of the proteins described

here are exported in a regulated fashion For example, IL-1b

and HMGB1 can be released from monocytes upon

stimulation with reagents that induce an inflammatory

response [6,104] At the same time, En2, IL-1b and HMGB1

are those factors among unconventionally secreted proteins

that appear to be exported from an endosomal

subcom-partment [25,106,116], which might be interpreted as some

kind of storage mechanism from which regulated secretion

of these factors can be triggered On the other hand, as

discussed above, nonclassical export of for example FGF-1

and galectin-1 are also regulated inducible processes, yet

there is no evidence that these factors are packaged into

intracellular vesicles prior to secretion The export process

of galectin-1 has been shown to be regulated based on cell

differentiation For example, during the differentiation of

muscle cells a massive increase of galectin-1 export has been

observed in correlation with the transition from myoblasts

to myotubes [7] Similarly, galectin-1 export from the

leukemia cell line K-562 can be stimulated by the addition of

differentiation-inducing agents such as erythropoietin [14]

It appears likely that differentiation-correlated galectin-1

export requires the synthesis of specific proteins, which is in

line with the time delay of induced galectin-1 export

Similarly, FGF-2 export has recently been shown to be

triggered by the expression of the Epstein–Barr virus protein

LMP-1 [15] This mechanism requires a functional NF-jB

signalling pathway [15], possibly indicating that LMP-1-mediated stimulation of FGF-2 export involves the induc-tion of a protein machinery based on de novo synthesis

Conclusions

As illustrated in Fig 1, at least four distinct pathways of unconventional protein secretion exist in mammalian cells that are fully functional in the absence of an intact ER/ Golgi system Various fundamental questions arise from these observations such as why do mammalian cells actually need additional secretory mechanisms besides the classical pathway? As noted previously, for the galectins it is relatively obvious that the alternative secretory pathway prevents their premature binding to glycolipids and glyco-proteins within the lumen of the classical secretory pathway [9] However, in other cases it is less clear why these cargo proteins are exported by unconventional means Other fundamental questions are: What are the molecular com-ponents that drive various mechanisms of nonclassical export? Why do proteins such as HMGB1 with completely unrelated functions also serve as paracrine signalling molecules upon unconventional release into the extracellular space? The answers to these questions are of exceptional interest as the cargo proteins secreted by unconventional means are factors whose biological functions are of tremendous importance to biomedical research For exam-ple, FGF-2 has been identified as a major target protein for the development of antiangiogenic drugs, as it has been shown that inhibitors of ternary complex formation between FGF-2 and its high and low affinity receptors [127] on the surface of target cells display antiangiogenic activity in vivo [128] Similarly, unconventional cell-surface expression of HASPB by Leishmania parasites appears to be tightly correlated with host cell infection [101,102] and therefore the HASPB export pathway might be an excellent target for the development of drugs against tropical and subtropical diseases termed the leishmanias These path-ways are in general attractive targets, because it may be possible to identify inhibitors that do not interfere with the essential function of the classical secretory pathway There-fore, elucidation of the molecular machineries controlling the various kinds of nonclassical export might provide a whole variety of novel target proteins suitable for drug design

So far, a biochemical analysis of the molecular machi-neries of nonclassical protein export has proven difficult because in many cases the export process is relatively inefficient Also, it is not yet clear whether unfolding of the various cargo proteins is required for unconventional secretion If so, classical methods employing dihydrofolate reductase [129] domains to trap cargo proteins at the site of translocation could be used in order to allowa biochemical analysis of the export apparatus It is also a major problem that, in most cases, only very limited information is available about the motifs that target cargo proteins to the nonclassical export routes Recently, novel assays have been developed which deploy fluorescence activated cell sorting to reconstitute unconventional protein export path-ways on a quantitative basis [50,79] This new approach might facilitate genetic screens in mammalian cells and

is compatible with systematic high throughput screening

technologies for the identification of lowmolecular mass

inhibitors of the processes described here Thus, the

elucidation of the molecular mechanisms of nonclassical

protein export from eukaryotic cells will not only solve a

fundamental problem in current cell biology but will also

lead to the identification of novel target proteins, with great

value for biomedical research

Acknowledgements

I would like to thank Britta Bru¨gger (Biochemie-Zentrum Heidelberg),

Tracy LaGrassa (Biochemie-Zentrum Heidelberg), Blanche

Schwap-pach (Zentrum fu¨r Molekulare Biologie Heidelberg), Ju¨rgen Bernhagen

(University Hospital RWTH Aachen) and Markus Ku¨nzler (ETH

Zu¨rich) for critical comments on the manuscript, as well as all members

of my laboratory for helpful discussions Work in the laboratory of the

author is supported by grants from the German Research Foundation

(DFG) and the Ministry of Science, Research and the Arts of the State

of Baden-Wu¨rttemberg.

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