Báo cáo khoa học: Plant RMR proteins: unique vacuolar sorting receptors that couple ligand sorting with membrane internalization pdf

In general, soluble proteins within the lumen of the endo-membrane system that are destined for the lyso-some⁄ vacuole traffic through the Golgi apparatus where they are recruited at the

Plant RMR proteins: unique vacuolar sorting receptors that couple ligand sorting with membrane internalization

Hao Wang1,2, John C Rogers3and Liwen Jiang1,2

1 Department of Biology, Centre for Cell and Developmental Biology, Chinese University of Hong Kong, China

2 State (China) Key Laboratory for Agrobaiotechnology, The Chinese University of Hong Kong, China

3 Institute of Biological Chemistry, Washington State University, Pullman, WA, USA

Introduction

Eukaryotic cells share a common organization of

organelles within their endomembrane systems, where

each is a membrane-bound compartment which defines

a separate environment for specific functions, and

dif-ferent organelles communicate with each other via

transport vesicles In general, a unique type of vesicle

is required for each step in traffic, and transmembrane

receptor proteins that are specific for one vesicle type

recruit cargo that will be transported from one

orga-nelle to another in the step mediated by that vesicle

[1–6] A general principle that applies across

eukary-otic species defines vesicle specificity: the cytoplasmic

coat proteins that cause a vesicle to bud from its

orga-nelle source interact with the specific receptor proteins

and cause them to partition with their cargo into the budding vesicle [7,8] Thus, in general terms, a sorting receptor is specific for one vesicle type that traffics

in one specific step between two endomembrane organelles

The endomembrane systems for animal, yeast and plant cells have in common the presence of an orga-nelle with an acidic lumenal pH that serves as a diges-tive compartment, the lysosome or vacuole [9,10] In general, soluble proteins within the lumen of the endo-membrane system that are destined for the lyso-some⁄ vacuole traffic through the Golgi apparatus where they are recruited at the trans-face into clathrin-coated vesicles (CCVs) by receptors that are unique

Keywords

lytic PVC; PA domain; pollen tube; PSV;

receptor; RING-H2 domain; RMR; storage

PVC; vacuole; VSR

Correspondence

L Jiang, State (China) Key Laboratory for

Agrobaiotechnology, The Chinese University

of Hong Kong, Shatin, New Territories,

Hong Kong, China

Fax: +852 2603 5646

Tel: +852 2609 6388

E-mail: ljiang@cuhk.edu.hk

(Received 31 March 2010, revised 30 June

2010, accepted 7 July 2010)

doi:10.1111/j.1742-4658.2010.07923.x

In receptor-mediated sorting of soluble protein ligands in the endomem-brane system of eukaryotic cells, three completely different receptor pro-teins for mammalian (mannose 6-phosphate receptor), yeast (Vps10p) and plant cells (vacuolar sorting receptor; VSR) have in common the features

of pH-dependent ligand binding and receptor recycling In striking con-trast, the plant receptor homology-transmembrane-RING-H2 (RMR) pro-teins serve as sorting receptors to a separate type of vacuole, the protein storage vacuole, but do not recycle, and their trafficking pathway results in their internalization into the destination vacuole Even though plant RMR proteins share high sequence similarity with the best-characterized mamma-lian PA-TM-RING family proteins, these two families of proteins appear

to play distinctly different roles in plant and animal cells Thus, this minire-view focuses on this unique sorting mechanism and traffic of RMR proteins via dense vesicles in various plant cell types

Abbreviations

CCV, clathrin-coated vesicle; CT, cytoplasmic tail; DV, dense vesicle; PA, protease-associated domain; PVC, prevacuolar compartment; PSV, protein storage vacuole; RMR, receptor homology-transmemebrane-RING-H2; SCAMP, secretory carrier membrane protein; TMD, transmembrane domain; VSR, vacuolar sorting receptor.

participate in sorting multiple ligand molecules.

In plant cells, the vacuolar sorting receptor (VSR)

proteins that participate in this trafficking step belong

to the BP-80 protein family [19–25] The best-studied

members of the family recognize a protein sequence on

ligand molecules that contain a central NIPR

(Asn-Pro-Ile-Arg) or similar motif [14,26] The

ligand-bind-ing specificity of one BP-80 protein was studied by

expressing in insect cells and then purifying from the

culture medium the BP-80 lumenal domain (termed

tBP-80) The most N-terminal 100 residues defined a

domain that is also highly conserved in the lumenal

sequences of what we termed receptor homology

domain-transmembrane sequence-RING-H2 (RMR)

proteins [27] Results from ligand-binding studies were

consistent with a model in which the ligand-binding

domain was contained within the N-terminal unique

region, and where the RMR domain contributed to

ligand binding [27] The receptor homology domains

found within BP-80 and RMR proteins were

subse-quently designated the protease-associated (PA)

domain which is important for substrate or ligand

binding [28,29] These experiments provided a reason

to hypothesize that RMR proteins themselves might

have a function in binding different types of ligands

and might also serve as sorting receptors However,

the native ligands for most VSRs and RMRs remain

to be identified and characterized in plants [30]

This possibility was subsequently considered in light

of observations indicating that plant cells could

con-tain two different types of vacuoles, a lytic or digestive

vacuole and a vacuole that stored proteins [1,16,31],

that the storage vacuole was served by an intracellular

pathway different from that trafficked by BP-80

[13,32], and that so-called ‘dense vesicles’ (DVs)

traf-ficked specifically to storage vacuoles [33]

The RMR protein family in plants

The identification and characterization of

PA-TM-RING proteins in plants were not achieved until

recently The plant RMR was first identified by

homol-ogy search using the pea VSR BP-80 N-terminal amino

acid sequence JR700 (Arabidopsis RMR1 or AtRMR1)

ligands in plants Structurally, similar to VSR, RMR is predicted to be a type I integral membrane protein that contains a typical N-terminal signal peptide, followed

by a PA domain likely responsible for protein–protein interaction [29] and a single transmembrane domain In contrast to the short cytoplasmic tail of VSR, the plant RMR has a long cytoplasmic tail (CT) with a typical

C3H2C3RING-H2 domain (Fig 1A)

The transmembrane domain (TMD) and CT sequences of the Arabidopsis AtRMR1⁄ 2 and the rice OsRMR1⁄ 2 are quite similar to the corresponding regions of the PA-TM-RING proteins from mice, chicken and humans, in particular, their TMD and RING-H2 domain sequences are highly conserved, with similar spacing between the domains (Fig 1B), indicating the probability of a similar function among these proteins The C3H2C3RING-H2 domain is asso-ciated with different biological functions in proteins from both mammalian cells and plants, such as func-tioning as transcriptional regulators [35,36] and as a ubiquitin–protein ligase [37–40] In mammalian cells, the function of the RING-H2 domains of the PA-TM-RING proteins has been relatively well studied [41–43], but the function of the RMR RING-H2 domains in plants remains elusive

RMR proteins traffic in a pathway different from that of BP-80

In order to gain insight into the function of RMR pro-teins, the intracellular localization and trafficking of RMR was studied in different plant cells and tissues [33,34,44–46] Immunofluorescence and immunoelec-tron microscopic studies with purified antibodies raised either to a recombinant protein containing part of the RMR lumenal domain, or to a peptide representing a unique sequence in the RMR protein cytoplasmic tail gave similar results In sections of tomato seeds where protein storage vacuoles (PSVs) are large and easily visualized, RMR proteins were present within PSVs and localized to large intravacuolar structures termed

‘crystalloids’; two other integral membrane proteins also colocalized to crystalloids [34] Biochemical analy-sis of purified crystalloid demonstrated a high ratio of

lipid to protein All of these observations were

consistent with the concept that crystalloid represented

intravacuolar arrays of lipid bilayers into which both

integral membrane proteins and soluble proteins were

packed [34] Subsequent studies using PSVs from

plants in the Brassicaceae family, which lack

micro-scopically defined crystalloids, demonstrated that

their PSVs also contained an internal, covalently

cross-linked network of integral membrane proteins, including RMR proteins [47] Thus the concept that formation of PSVs in plant seed embryos involves internalization of membranes containing specific inte-gral protein markers may be generally applicable

A second experimental approach was used to define the pattern of RMR protein organelle traffic [34] In these experiments, a chimeric integral membrane

repor-A

B

Fig 1 Comparison between plant RMR proteins and mammalian PA-TM-RING proteins (A) Structures of a typical plant RMR protein the rice OsRMR1, BP-80, the pea VSR, two mammalian PA-TM-RING proteins MmRNF13 and MmGRAIL RMR is predicted to be a type I inte-gral transmembrane protein containing an N-terminal signal peptide (SP) and a PA domain at its N-terminus, a single TMD and a long CT with

a C3H2C3RING finger domain The conserved PA and RING domains among the plant RMRs and the mammalian PA-TM-RING family pro-teins are highlighted in boxes The two conserved Asn-linked glycosylation sites in the lumenal domain of the plant RMR (OsRMR1) are indi-cated by asterisks (B) Amino acid sequence comparisons of TMD and CT regions of selective AtRMRs, OsRMRs and PA-TM-RING H2 proteins from mouse, chicken and humans Gray boxes indicate highly conserved residues (C) Phylogenetic analysis of selective plant RMR and PA-TM-RING proteins using neighbor-joining algorithm with 1000 cycles of bootstrap resampling as indicated (D) Phylogenetic analysis

of the five Arabidopsis RMRs (AtRMRs) and the two rice RMR (OsRMRs) using neighbor-joining algorithm with 1000 cycles of bootstrap re-sampling as indicated.

(designated Re-B-B, known to traffic from ER to

Golgi to lytic PVC), and in a second case containing

the BP-80 transmembrane sequence but with the

alpha-tonoplast intrinsic protein (a PSV marker)

cyto-plasmic tail (designated Re-B-alpha, known to traffic

directly from ER to a PSV PVC) The proaleurain

reporter moiety would be proteolytically processed by

a specific maturase [48,49] if it reached the lytic PVC,

and traffic into the Golgi would be assessed by

evalu-ating whether the reporter protein acquired complex

modifications to its two Asn-linked oligosaccharide

chains [13] The results are summarized in Table 1,

and document that the RMR reporter protein entered

the Golgi apparatus because it acquired complex

glycans, but it did not traffic to the lytic PVC [34]

Thus, RMR proteins trafficked through the Golgi

apparatus in a pathway distinct from that of BP-80,

and were directed to a protein storage vacuole

equiva-lent in the suspension cultured protoplasts that also

contained alpha-tonoplast intrinsic protein, whereas in

plant seed embryos the RMR proteins were

concen-trated in internal membrane arrays in PSVs

The growing pollen tube is an ideal single-cell model

system to study protein trafficking and their functions

in the secretory and endocytic pathways in plants The

dynamics and function of BP-80 and secretory carrier

membrane protein (SCAMP) were also recently

char-acterized in growing lily (Lilium longiflorum) pollen

tube [25] SCAMP localized to early endosomes,

plasma membrane and cell plate in plant cells [50]

endosomes 50–200 nm in size [50] By contrast, GFP– BP-80⁄ GFP–LIVSR were found to locate throughout the pollen tubes except the apical clear zone region (Fig 2B) and were concentrated in  0.2-lm diameter punctate organelles that represent prevacuolar com-partments for the lytic vacuole In addition, microin-jection of VSR or SCAMP antibodies significantly reduced the growth rate of the lily pollen tubes [25] Because VSRs mediate vacuolar protein transport [51], whereas SCAMPs may play roles in endocytosis [50,52] as well as cell plate formation [48], these results together suggest that both VSR and SCAMP are required for pollen tube growth, likely working together in regulating protein trafficking and mem-brane flow in the secretory and endocytic pathways which need to be coordinated in order to support pollen tube elongation

RMR proteins may also function in pollen tube growth because microarray data analysis of gene expression in Arabidopsis (GENEVESTIGATOR, https://www.genevestigator.com/gv/index.jsp) shows that AtRMR3 is highly expressed in pollen compared with other AtRMRs in various tissues (unpublished results) We have thus recently taken a similar approach to study the dynamics and distribution of GFP-tagged RMR proteins using the same pollen tube transient expression system As shown in Fig 2C, when transiently expressed in a tobacco pollen tube,

a weak GFP–AtRMR3 signal was diffusely distributed throughout the length of the growing pollen tube but

Table 1 Exploration and determination of RMR or VSR protein trafficking via reporter fusion protein TMD, transmembrane domain;

CT, cytoplasmic tail; a-TIP, alpha-tonoplast intrinsic protein; LIVSR, lily vacuolar sorting receptor; LISCAMP, lily secretory carrier membrane protein; GFP, green fluorescent protein; TGN, trans-Golgi network; ER, endoplasmic reticulum; NA, not determined.

Reporter protein

Complex glycan

Proaleurain maturation Trafficking pathway Lumenal proaleurain reporter domain + BP-80 TMD and CT (Re-B-B) Yes Yes ER to Golgi to lytic PVC

Lumenal proaleurain reporter domain + AtRMR TMD and CT (Re-R-R) Yes No ER to Golgi to storage PVC Lumenal proaleurain reporter domain + BP-80 TMD + a-TIP CT (Re-B-alpha) No No ER to storage PVC

vacuole in pollen tube

TGN to lytic vacuole in pollen tube

missing from the tip region, and concentrated within

some large  1–2-lm organelles (Fig 2C) that were

mobile (data not shown), a pattern that was different

from those of GFP–LlSCAMP (Fig 2A) Given the

known association of RMR proteins with protein

stor-age vacuoles or their PVCs in other plant systems, we

tentatively identify these structures as pollen tube PSVs

or their PVCs, although a firm identification will

require further colocalization studies with markers for

other organelles and⁄ or immunogold EM studies

Role of RMR proteins as sorting

receptors

The ability of the AtRMR2 lumenal domain to bind

potential protein ligands was evaluated using the

recombinant protein expressed in insect suspension

cul-ture cells from which it was secreted into the culcul-ture

medium and purified [44,45] It should be noted that

all RMR lumenal domains contain two conserved sites

for Asn-linked glycosylation (Fig 1A), and use of the

insect cell expression system allowed assurance that

proper glycosylation would be achieved [44] This

con-sideration was relevant because the relatively large size

of such glycans would impose steric limitations on

interactions of the relatively small RMR protein with

potential ligands

The experimental approach evaluated interactions

with two distinct types of known vacuolar sorting

determinant sequences The first type is the NPIR

(Asn-Pro-Ile-Arg) motif recognized by the VSR

pro-teins, whereas the second type is demonstrated by two

different C-terminal propeptide sequences representing the class of targeting signals that have no apparent sequence conservation but the function of which requires placement at the C-terminus of ligand proteins [31,53] It had been hypothesized that the latter direc-ted proteins into the pathway to PSVs [54], and subse-quent studies using genetic approaches in Arabidopsis identified a specific SNARE complex, important for membrane fusion in eukaryotes, to be essential for traffic through the pathway required for vacuolar tar-geting of ligands carrying C-terminal vacuolar sorting determinants (defined as the PSV pathway), but not the pathway for traffic to a lytic vacuole [55,56] Park et al [44] assessed binding of the AtRMR2 lumenal domain to synthetic peptides of defined sequences that were coupled to agarose beads AtRMR2 bound specifically to known C-terminal vacuolar sorting determinant sequences, but only if they were presented with a free C-terminus Interestingly, binding of the RMR protein to these C-terminal sorting determinant sequences was not pH dependent; in contrast to the interaction of BP-80 with its sequence-specific ligands, the RMR protein could not be eluted from the peptide– agarose beads by treatment at pH 4 In addition, specific binding was blocked by the C-terminal addition of two Gly residues, a modification known to prevent function

in vacuolar sorting [53] Specific binding to peptides car-rying sequence-specific sorting determinants was not observed Thus, RMR proteins specifically bind to pep-tides corresponding to sorting determinants for the PSV pathway, which is distinct from the pH-dependent BP-80⁄ AtVSR1 sorting pathway to the lytic vacuole

A

B

C

Fig 2 Dynamics distribution of RMR vs.

VSR and SCAMP in growing lily pollen tube.

GFP fusions constructs with the lily

secretory carrier membrane protein 4

(GFP–LlSCAMP4) (A), the lily vacuolar

sorting receptor 2 (GFP–LlVSR2) (B) and the

Arabidopsis RMR3 (GFP–AtRMR3) (C) were

transiently expressed in growing lily pollen

tubes (A ⁄ B) or tobacco pollen tube (C)

respectively via particle bombardment,

followed by confocal imaging as previously

described [25] Scale bar, 25 lm.

interaction of the recombinant proteins to which they

are attached The obtained results indicated that BP-80

preferentially interacted with the vacuolar targeting

sequence of lytic vacuole marker proaleurain rather

than the C-terminal propeptide of the PSV marker

chitinase [57] Conversely, AtRMR2 preferentially

interacted with the chitinase C-terminal propeptide but

not with the proaleurain targeting sequence These

results were consistent with the in vitro binding assay

results and indicated that the AtRMR2 lumenal domain

could interact in a specific manner with the chitinase

C-terminal vacuolar sorting determinant in vivo

In a separate series of experiments, the reporter

pro-tein Re-R-R with either GFP or monomeric red

fluor-escent protein (mRFP) inserted into its cytoplasmic

tail was transiently expressed in the suspension culture

protoplasts Consistent with previous findings that

endogenous RMR proteins were internalized into PSVs

in developing seed embryos, Re-R-R tagged with either

fluorescent molecule was present in small punctate

cytoplasmic organelles, but also was internalized into

the lumen of the protoplasts’ central vacuoles Thus,

traffic of these proteins, which as previously shown

[34] was determined by sequences in the AtRMR2

cytoplasmic tail, resulted in the cytoplasmic tails

con-taining the fluorescent tags being transferred from the

cytoplasm to the vacuole lumen

A different study used the lumenal domain of

AtRMR1 expressed in bacterial system for binding

studies [46] Those authors found that the

At-RMR1 protein bound to C-terminal vacuolar sorting

sequences but not to sequence-specific sorting

sequences, and that binding was pH dependent and

was abolished at pH 4 In addition, they presented

data that argued for recycling of the AtRMR1 protein

in transient expression experiments in Arabidopsis

sus-pension culture protoplasts These results and those

obtained for AtRMR2, as well as experiments

localiz-ing endogenous RMR proteins in vivo [33,34], appear

to be contradictory However, the possibility remains

that AtRMR1 has substantially different

ligand-bind-ing properties and patterns of traffic within cells

Future genetic study using knockout mutants of

individual AtRMRs or coexpression of AtRMR1 and

teins which are predominantly present in CCVs Using quantitative analyses at the electron microscope level, those authors demonstrated that globulin-type storage proteins form aggregates in the cis-Golgi that partition

at the periphery of cisternae and then move sequen-tially towards the trans-face where they bud off as DVs By contrast, BP-80 receptors were localized pre-dominantly at the trans-Golgi and were associated with CCVs [58] They therefore proposed a novel model whereby spatial regulation of sorting within the Golgi apparatus might explain how traffic of storage proteins

to PSVs could be separated from traffic of proteins destined to be carried by CCVs to the lytic PVC

In a subsequent study, those authors quantitatively analyzed the distribution of AtRMR2, Arabidopsis AtVSR proteins (BP-80 homologs) and the storage protein cruciferin in the Golgi apparatus and vesicles during Arabidopsis embryo development [33] In con-trast to Otegui et al (2006) [59], but consistent with prior results in the pea system, cruciferin was present predominantly at the periphery in the cis and medial cisternae and in DVs AtVSR labeling was predomi-nantly at the trans-face and in CCV, with very small amounts associated with DVs By contrast, labeling for AtRMR2 in the Golgi and DVs was very similar

to that for cruciferin These results were interpreted to support the concept that RMR proteins were associ-ated with sorting of storage protein aggregates into DVs Consistent with findings from other studies, labeling for AtRMR2 on organelles representing PVCs was predominantly internal, providing further support that these proteins are internalized into organelle lumens during their traffic to the PSV Such internali-zation would remove the possibility that AtRMR2 could recycle back to the Golgi apparatus to partici-pate in more than one round of ligand sorting

How could RMR proteins serve as efficient sorting receptors if they do not recycle? The aggregation model for storage protein sorting [58] may provide an explanation By interacting with an aggregate of many storage protein molecules as the aggregate is sorted into a DV, a limited number of RMR proteins could participate in DV coat protein formation and effi-ciently promote sorting [33,44]

The process of internalization of RMR proteins into

prevacuolar organelles would result in removal of

cytoplasmic tails of the proteins from the cytoplasm

The RING-H2 domain found in mammalian RMR protein homologs has been shown to function as a ubiquitin–protein ligase [37,38] There is no direct

Fig 4 Working model of RMR proteins in plants (A) Subcellular localization and dynamics of RMRs in developing seeds In developing tomato and tobacco seeds, RMR is found in the crystalloid of PSV, the storage PVC or DIP organelle; whereas in developing Arabidopsis seeds RMR were found in DVs [34] (B) Subcellular localization and dynamics of RMR, VSR and SCAMP in growing pollen tube Shown is a working model on the localization, dynamics and possible functional roles of VSR, SCAMP and RMR proteins in germinating pollen tubes SCAMP is highly enriched in the apical region of the pollen tube which is missing the VSR [25] In addition to a possible ER–Golgi–trans-Golgi network–PVC ⁄ multivesicular body–vacuole transport pathway [25], VSR ⁄ BP-80 could also reach the plasma membrane from the trans-Golgi network and then internalize because VSR was also found in PM in addition to multivesicular body or PVC in immunogold EM study (our unpublished results) Similarly, SCAMP could reach the plasma membrane from either Golgi or trans-Golgi network and internalize from the plasma membrane via endocytosis colocalizing with the internalized endocytic marker FM4-64 The SCAMP-positive small vesicles enriched in the apical region are believed to be derived directly from the Golgi apparatus or via trans-Golgi network and endocytic vesicles from plama membrane RMR may mediate protein transport from Golgi apparatus and reach a yet-to-be identified storage organelle or PVC distinct from the SCAMP-positive trans-Golgi network ⁄ early endosome and the VSR-positive multivesicular body ⁄ PVC in the same growing pollen tube Both VSR and SCAMP were found to reach the vacuole lumen in immunogold EM, presumably for degradation [25].

Fig 3 Evidence for the presence of ubiquitin in protein storage vacuole crystalloid Immunogold EM labeling [24] with anti-ubiquitin sera was performed on ultrathin sections prepared from high-pressure freezing ⁄ frozen substituted developing tobacco seed embryo cells A typi-cal PSV in these cells contains three distinct subcompartments (crystalloid, matrix and globoid as indicated) (A), in which gold particles are mainly found in the crystalloid as indicated by arrows (B) No labeling with secondary antibody alone was observed (data not shown).

consistent with the concept that RMR proteins are

internalized into the PSV as it develops, and

intermo-lecular ubiquitination might help explain the

observa-tion that ‘crystalloid’ proteins from Brassica napus

were cross-linked in a manner that resisted treatment

with disulfide reducing agents [47] Such hypothesis of

ubiquitin-mediated cross-linking during internalization

of proteins into the PSV could be tested in future

experiments by isolation and biochemical analysis of

PSVs

Both the mammalian GRAIL and RNF13 proteins

affect complex functions in cells where they are

expressed In the case of the RNF13 protein, the

cyto-plasmic tail is cleaved from attachment to the TMD

during traffic to endosomes; the now free cytoplasmic

tail with its ubiquitin–protein ligase activity has been

postulated to provide a mechanism for activation of

signaling pathways that would affect cell functions and

fate [37] Although genes encoding the beta and

gamma secretase proteases that are hypothesized to

participate in such a cleavage process [37] are not

pres-ent in plant genomes [60], it is possible that some other

mechanism for cleavage of plant RMR protein

cyto-plasmic tails within the basic region separating the

transmembrane and RING-H2 domains conserved in

both plant and mammalian proteins (as indicated in

Fig 1A,B) might exist Thus there may be an

advan-tage to the cell to have these relatively abundant

pro-teins removed from the cytoplasm as they reach the

terminus of their trafficking pathway Whether the free

tail would participate in some signaling process

remains to be tested experimentally

Conclusion and future perspective

In conclusion, Fig 4A summaries the subcellular

local-ization, trafficking and possible function of RMRs in

developing seeds, where RMR-mediated storage

protein sorting is achieved via concentration sorting in

storage PVC [or dark intrinsic protein (DIP)

organ-elles] or DVs (Fig 4A) In addition, the three integral

memebrane proteins, RMR, VSR and SCAMP, show

distinct patterns of subcellular localization and

dynam-ics in the same growing pollen tubes (Fig 4B),

indicat-truncated VSR or RMR proteins would bring along their native cargoes into the culture media to be identi-fied by LC-MS⁄ MS analysis [30], however, this approach would be difficult to carry out for RMR cargo identification if RMR binds to aggregates Such

a biochemical⁄ cell biology approach for functional characterization of VSR and RMR, as well as their cargo proteins in plants, will likely generate novel information to complement genetic approaches Published studies of the luminal domain of plant RMRs suggest that these proteins function as sorting receptors for transporting storage proteins to PSVs in plants However, the functional roles of the RMR C-terminal RING-H2 domain remain largely unknown compared with that of the mammalian PA-TMD-RING proteins Because the PA-TMD-RING domains are highly conserved between the plant RMR and the mamma-lian PA-TMD-RING proteins (Fig 1A–C) and because ubiquitin was localized in the PSV crystalloid where RMR proteins are concentrated (Fig 3), it is reasonable to hypothesize that plant RMR proteins may also have a similar ubiquitin–protein ligase activity Such hypothesis can be tested via in vitro ubiquitin–protein ligase activity analysis in future experiments

Acknowledgements Our work has been supported by grants from the Research Grants Council of Hong Kong (CUHK488707, CUHK465708, CUHK466309, CUHK

466610 and HKUST6⁄ CRF ⁄ 08), UGC-AoE, CUHK Schemes B⁄ C

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