Tài liệu Báo cáo khoa học: Oxygen tension regulates the expression of a group of procollagen hydroxylases docx

These findings indicate that hypoxia stimulates the gene expression of a cluster of hydroxylases that are indispensible for collagen fiber formation.. 3T3 fibroblasts [8], like renal mesang

Oxygen tension regulates the expression of a group of procollagen hydroxylases

Karl-Heinz Hofbauer1, Bernhard Gess1, Christiane Lohaus2, Helmut E Meyer2, Do¨rte Katschinski3

and Armin Kurtz1

1

Institut fu¨r Physiologie der Universita¨t Regensburg, Germany;2Medizinisches Proteom, Center der Ruhr, Universita¨t Bochum, Germany;3Abteilung Zellphysiologie der Martin-Luther Universita¨t Halle, Germany

In this study, we have characterized the influence of hypoxia

on the expression of hydroxylases crucially involved in

col-lagen fiber formation, such as prolyl-4-hydroxylases (Ph4)

and procollagen lysyl-hydroxylases (PLOD) Using the rat

vascular smooth muscle cell line A7r5, we found that an

hypoxic atmosphere caused a characteristic time-dependent

five- to 12-fold up-regulation of the mRNAs of the two P4h

a-subunits [aI (P4ha1) and aII (P4ha2)] and of two

lysyl-hydroxylases (PLOD1 and PLOD2) These effects of

hyp-oxia were mimicked by the iron-chelator deferoxamine

(100 lM) and by cobaltous chloride (100 lM) The hypoxic

induction of these genes was also seen in the mouse

juxta-glomerular As4.1 cell line and mouse hepatoma cell line

Hepa1 but was almost absent in the mutant cell line Hepa1C4, which is defective for the hypoxia-inducible transcription factor 1 (HIF-1) In addition, the enzyme expression was induced by hypoxia in mouse embryonic fibroblasts but not in embryonic fibroblasts lacking the HIF-1a subunit These findings indicate that hypoxia stimulates the gene expression of a cluster of hydroxylases that are indispensible for collagen fiber formation Strong indirect evidence, moreover, suggests that the expression of these enzymes during hypoxia is coordinated by HIF-1

Keywords: prolyl hydroxylase; lysyl hydroxylase; protein disulfide isomerase; hypoxia inducible transcription factor

In a variety of tissues, an hypoxic environment favors the

formation of collagen deposits Such an hypoxia-related

collagen formation has a clear (patho)physiological impact

for wound healing in the skin, for the remodeling of small

muscular pulmonary arteries in hypoxia-induced pulmonary

hypertension and possibly also for cardiac hypoxia The

formation of collagen fibers and deposits is a multi-step

event that includes procollagen protein synthesis, prolyl

hydroxylation as requirement for triple helix formation, lysyl

hydroxylation, protein folding, maturation and secretion,

and finally covalent cross-bridging between collagen fibers

through the activity of the lysyloxidase Which of these steps

are directly triggered by hypoxia and how this is

accom-plished is not well understood It has been reported that

hypoxia increases mRNA levels for different procollagens in

the lung [1,2] and heart in vivo [3] In vitro studies suggest that

this effect of hypoxia on procollagen gene expression might

be isoform and cell-type specific Thus, hypoxia stimulates

procollagen I formation in renal [4], dermal [5], and cardiac

fibroblasts [6], but neither in fetal lung fibroblasts [7] nor in

3T3 fibroblasts [8] 3T3 fibroblasts [8], like renal mesangial cells [9], however, increase the gene expression of procol-lagen IV in response to hypoxia The effect of hypoxia on the activity of the prolyl-4-hydroxylase (PHD-4 or P4h) is clearer; it is crucially required to enable triple helix formation and has been found to be increased in its activity in response

to hypoxia [7,10–12] For the PHD-4(P4h) heterotetramer enzyme (a2b2) there exist two isoforms with a variable a-subunit (aI or aII) and a constant b-subunit, which is identical to protein disulfide-isomerase (PDI) [13] In vitro studies have shown recently a moderate increase of aI protein and gene expression in fetal lung fibroblasts during hypoxia [14], which is likely mediated by the hypoxia inducible transcription factor HIF-1 [14] Whether hypoxia also triggers the gene expression of aII is not yet known Although PDI as the b-subunit is considered to be expressed

in excess, there is a report that hypoxia also causes a delayed increase of PDI expression in cultured astrocytes [15] Whether such an hypoxic stimulation of PDI expression is a more general phenomenon and what the possible underlying mechanism could be, is also unknown In addition to prolyl hydroxylation, maturation of procollagen also requires the hydroxylation of lysin residues mediated by procollagen lysyl-hydroxylases (PLOD), for which three isoforms exist [16], two of which, namely PLOD1 and PLOD2, are more closely related and colocalize with P4h in the endoplasmic reticulum [17] Whether the homodimeric PLODs are triggered by hypoxia is also unknown

Screening a rat vascular smooth muscle cell line for hypoxia-induced proteins revealed a clear stimulation of P4ha1 and P4ha2 protein expression that was absent in a cell line defective for HIF-1 As these findings suggested a more

Correspondence to A Kurtz, Institut fu¨r Physiologie, Universita¨t

Regensburg, D-93040 Regensburg, Germany.

Fax: + 49 941 9434315, Tel.: + 49 941 9432980,

E-mail: armin.kurtz@vkl.uni-regensburg.de

Abbreviations: HIF-1, hypoxia inducible transcription factor 1; PDI,

protein disulfide isomerase; Ph4, prolyl-4-hydroxylases; PLOD,

pro-collagen lysyl-hydroxylases; SDS/PAGE, sodium dodecyl sulfate/

polyacrylamide gel electrophoresis; UPR, unfolded protein response.

(Received 31 July 2003, revised 8 September 2003,

accepted 19 September 2003)

general HIF-1-related effect of hypoxia on the expression of

the critical hydroxylases for collagen fiber formation, this

study aimed to characterize the influence of hypoxia on the

gene expression of these hydroxylases in more detail

Materials and methods

Cell cultures

Rat aortic vascular smooth muscle cells (A7r5) from BDXI

rats (ATCC CRL 1444) were cultured in 75 cm2 flasks

(Sarstedt) with 15 mL Dulbecco’s modified Eagle’s medium

containing 10% fetal bovine serum and

penicillin/strepto-mycin (P/S; 10 U/10 lgÆmL)1)(Biochrom), kept in an

atmosphere of 10% CO2 (v/v), 21% O2 and 69% N2 at

37C Medium was changed every second day and cells were

confluent on days 7–10 after splitting, which was achieved

with trypsin–EDTA for 5 min at 37C For the

experi-ments, cell cultures (triplicates) were incubated in 21% O2

(i.e normoxia) or 1% O2, 10% CO2, 89% N2(i.e hypoxia)

for up to 24h Additional culture dishes were incubated at

21% O2with either cobalt(II) chloride (100 lmolÆL)1) or

with desferoxamine (200 lmolÆL)1) for 12 h

Mouse As4.1 cells [18] were incubated under the

afore-mentioned conditions for 4.5 h

Mouse hepatoma Hepa1 cells, and their subclone

Hepa1C4, which produces defective ARNT (HIF-1b) [19]

due to a point mutation [20] rendering the cells unable to

form active HIF [21], were grown under the above

mentioned conditions For the experiments the cells were

incubated either at 0.5% O2, 10% CO2 balance N2 (i.e

hypoxia) or at 21% O2, 10% CO2 balance N2 with

deferoxamine (200 lmolÆL)1) for 24h

Mouse embryonic fibroblasts with normal (+/+) and

with a disrupted (–/–) gene for HIF-1a [22] were grown

under the above-mentioned conditions The cells were

incubated either at 0.5% O2(i.e hypoxia) or at 21% O2with

deferoxamine (100 lmolÆL)1) for 24h

Preparation of protein samples

After removal of cell culture medium, cell were washed three

times with ice-cold NaCl/Piand then scraped off in lysis

buffer (300 lL per 75 cm2 flask) consisting of 7 molÆL)1

urea, 2 molÆL)1thiourea, 2% CHAPS, 1% dithiothreitol,

PharmalyteTM pH 3–10 (Pharmacia, Uppsala, Sweden),

supplemented with protease inhibitors (Complete,

Boeh-ringer Mannheim, Germany) The material was then

homo-genized with an Ultraturrax (3· 10 s) and further sonicated

for 3· 10 s The homogenate was then allowed to stand at

room temperature for 60 min prior to ultracentrifugation at

80 000 g at 15C for 1 h Aliquots of the clear supernatant

were frozen in liquid nitrogen and stored at )80 C For

determination of the protein concentration, protein was

precipitated with 10% trichloroacetic acid in acetone and

resuspended in 0.1MNaOH Protein concentration was then

determined with the Bio-Rad protein assay (Bio-Rad, Int.)

Two-dimensional PAGE

Protein (150 lg) for silverstained gels and for

Coomassie-blue staining (600 lg) were loaded for each sample onto the

first dimension strips A linear immobilized pH gradient (pH 5.0–6.0 IPG buffer 18; Pharmacia) was used as the first dimension Hydration of gel strips and sample application was performed at 50 V for 15 h For protein separation, a step-voltage protocol was applied (1 h 150 V, 3 h 500 V,

1 h 1000 V, gradient to 8000 V within 0.5 h) A total volt– hour product of 60 kVh was used for 150 lg protein and 110 kVh for 600 lg protein Afterwards, the strips were incubated in 50 mmolÆL)1 Tris/HCl (pH 6.8), urea

6 molÆL)1, glycerol 30%, dithiothreitol 65 mmolÆL)1, 2% sodium dodecyl sulfate (SDS) for 20 min at room tempera-ture followed by incubation in 50 mmolÆL)1 Tris/HCl (pH 8.8), urea 6 molÆL)1, glycerol 30%, iodoacteamide

140 mmolÆL)1, and 2% SDS for another 20 min For the second dimension, a vertical gradient slab gel of 8–18% acrylamide was used and SDS/PAGE was performed at

8 mA per gel at 13C for 4h followed by 30 mA for 12 h

At the end of the second dimension, the gels were removed from the glass plates

Staining of two-dimensional PAGE The gels were fixed and stained with silver according to standard protocols [23] The gels were then scanned (Image Scanner Sharp JX-330, Amersham Biosciences) and ana-lyzed with theIMAGE3.1 analysis software package (Amer-sham Bioscience) Each spot was matched from one gel to another and the relative volume of matched spots was compared For preparative protein analysis higher amounts

of protein were loaded for two-dimensional PAGE and the protein spots were then stained with colloidal Coomassie-blue

Protein sequence analysis Coomassie-blue stained spots were excised from the gels and were subjected to ESI-MS analysis [24] Sequences obtained with ESI-MS analysis were then compared with the mouse and rat subset of the NCBInr.fasta protein database RNA isolation

Total RNA was extracted from freshly harvested cells and from frozen tissues according to the protocol of Chomczynski and Sacchi [25]

Real time PCR analysis Real time PCR was performed in a Light Cycler (Roche, Germany) All PCR experiments were performed using the Light Cycler DNA Master SYBR Green I kit provided by Roche Molecular Biochemicals (Mannheim, Germany) Each reaction (20 lL) contained 2 lL cDNA, 3.0 mM MgCl2, 1 pmol of each primer and 2 lL of Fast Starter Mix (containing buffer, dNTPs, SYBR Green and hotstart Taq polymerase) The primers used are summarized in Table 1

The amplification program consisted of one cycle at

95C for 10 min, followed by 40 cycles with a denaturing phase at 95C for 15 s, an annealing phase of 5 s at 60 C and an elongation phase at 72C for 15 s A melting curve analysis was carried out after amplification to verify the

accuracy of the amplicon For verification of the correct

amplification, PCR products were analyzed on an ethidium

bromide stained 2% agarose gel

In each real-time PCR run for each gene product under

investigation and for b-actin a calibration curve was

included, that was generated from serial dilutions (1 : 1,

1 : 10, 1 : 100, 1 : 1000) of a cDNA generated from the

pooled RNA of the normoxic (control) cultures (at the

different time points) of the respective experimental series

(standard cDNA) Analysis of the individual unknowns

therefore yielded values relative to this pool Data are

presented as the relative mRNA/b-actin mRNA ratio The

mRNA/b-actin mRNA ratio of the time standards (pools)

cDNA was set to 1.0 (i.e normoxia, 21% oxygen) Data

are therefore expressed as relative values related to

normoxia

Statistics

Levels of significance between groups were calculated using

ANOVAtest followed by Bonferoni’s reduction for multiple

comparisons P < 0.05 was considered significant

Results

Screening the rat vascular smooth muscle cell line A7r5 for hypoxia (1% oxygen for 24h) induced proteins by two-dimensional electrophoresis revealed a highly reproducible two- to fourfold up-regulated abundance of two proteins (Fig 1) One of them appeared with two slightly different masses around 60 kDa on SDS/PAGE with a pI around

pH 5.7 Analysis of tryptic peptides by ESI-MS identified these proteins as rat prolyl-4-hydroxylase aI subunit (P4ha1) The slightly different molecular masses of the aI subunit probably result from different glycosylation [26] The second protein appeared as a single spot with a somewhat smaller molecular mass on SDS/PAGE than the prolyl-4-hydroxylase aI subunit, but with a rather similar pI

of pH 5.7 This spot was identified by ESI-MS as rat prolyl-4-hydroxylase aII subunit (P4ha2) Repeated analysis of different gel runs using different protein extracts from A7r5 cells indicated that the prolyl-4-hydroxylase aI spot was increased two to 2.5-fold and the prolyl-4-hydroxylase aII spot was increased three- to fourfold after exposure of the cells to 1% oxygen for 24h

Table 1 Primers used for real-time PCR of procollagen, prolylhydroxylases, PDI and lysylhydroxylases mRNAs.

Mouse (gi:836897) prolylhydroxylase alpha I

Rat (gi:474939) prolylhydroxylase alpha I

Mouse (gi:6754969) prolylhydroxylase alpha II

Rat (gi: 6754969) prolylhydroxylase alpha II

Mouse (gi: 20913928) and rat (gi: 6981323) protein disulfide isomerase

Mouse (gi: 6755105) lysylhydroxylase I

Rat (gi: 409058) lysylhydroxylase I

Mouse (gi: 6755107) lysylhydroxylase II

Rat (gi: 6755107) lysylhydroxylase II

Mouse (gi: 424103) procollagen Col1a1

Rat (gi: 807263) procollagen Col1a1

Mouse and rat (gi: 6671508) b-actin

To investigate the underlying mechanism for the

increased expression of the P4h subunits in response to

hypoxia, we next analyzed mRNA expression for P4ha1

and P4ha2 mRNA Real-time PCR analysis revealed a

characteristic time-dependent increase of the mRNA

abun-dance in A7r5 cells incubated at 1% oxygen for P4ha1 and

P4ha2, starting around 4 h of hypoxia, the induction of

P4ha2 mRNA being stronger than that of P4ha1 (Fig 2A)

In view of this concordant regulation, we further considered

the possibility that also the expression other hydroxylases

involved in collagen fiber formation might be regulated by

the cellular oxygen tension In fact, it turned out that also

the mRNAs for lysyl hydroxylases I and II (PLOD1 and -2)

increased clearly during hypoxia, in a very similar fashion to

the mRNAs for the prolyl hydroxylases In addition, also

the mRNA for protein disulfide isomerase (PDI), as the

b-subunit of prolyl hydroxylases, increased in A7r5 cells,

although significantly delayed and to a lesser extent After

24h of hypoxia the mRNA abundance was five-, 12-, six,

seven- and fivefold increased for P4ha1, P4ha2, PDI,

PLOD1 and PLOD2, respectively Notably the abundance

of procollagen Ia was not changed by hypoxia (Fig 2B)

Very similar results to those with hypoxia were obtained,

when A7r5 cells were incubated with the iron-chelator

deferoxamine (100 lmolÆL)1) at ambient oxygen tension

(21% O2) After 24h mRNA abundance was increased

five-, 16-, two-, five- and 10-fold, for P4ha1, P4ha2, PDI,

PLOD1 and PLOD2, respectively (Fig 3A), whilst the

mRNA abundance for procollagen Ia was unchanged

Also, cobalt(II) chloride (100 lmolÆL)1) moderately

increased the mRNAs of the hydroxylases, but not of

procollagen Ia mRNA (Fig 3B)

To test for the cell and species specificity of the changes of the enzyme expression in response to hypoxia, we also analyzed the mouse juxtaglomerular cell line As4.1 As we have recently found that these cells respond to hypoxia rather rapidly [27], we exposed the cells to either hypoxia (0.5% oxygen) or deferoxamine (100 lmolÆL)1) for only 4.5 h and assayed the mRNA levels of the procollagen hydroxylases By these maneuvers, P4ha1 mRNA increased five- to eightfold, P4ha2 mRNA 25- to 33-fold, PDI mRNA twofold, PLOD1 mRNA fivefold, and PLOD2 mRNA twofold (Fig 4)

As the combination of the stimulatory effects of hypoxia, deferoxamine and cobalt suggested a possible involvement

of the hypoxia-inducible transcription factor (HIF) in the activation of P4h, and PLOD gene expression by hypoxia,

we further examined the expression of these genes in a cell line with a defective HIF, namely the murine hepatoma cell line Hepa1C4 In the control cell line, Hepa 1 both hypoxia (0.5% oxygen) and deferoxamine (100 lmolÆL)1) clearly induced P4ha1 (four- and sevenfold) and P4ha2 mRNA (seven- and fourfold) and to a lesser extent also PDI mRNA (two- and 1.5-fold), whilst procollagen Ia mRNA remained unchanged after 12 h of stimulation (Fig 5A) The stimu-latory effect of hypoxia and of deferoxamine on P4ha1 and P4ha2 mRNA and PDI mRNA was almost abrogated in Hepa1C4cells (Fig 5B), supporting the assumption that the expression of these genes was driven by HIF Unfor-tunately, mRNA levels for the PLOD mRNAs were too low

to allow reasonable semiquantification in both Hepa1 and Hepa1C4cells

This first indication about an essential role of HIF in the triggering of prolylhydroxylase gene expression was further Fig 1 Two-dimensional electrophoresis of proteins isolated from the rat vascular smooth muscle cell line A7r5 The indicated protein spots were up-regulated by exposure of the cells to hypoxia (1% O 2 ) for 12 h.

corroborated in mouse embryonic fibroblasts lacking the HIF-1a subunit As shown in Fig 6 hypoxia, deforoxamine and cobalt stimulated the expression of P4ha1, P4ha2, PDI, PLOD1 and PLOD2 mRNAs in wild-type embryonic fibroblasts, but not in embryonic fibroblasts lacking the HIF-1a subunit

As the enzymes involved in collagen formation are important for the correct folding of the protein, it is in principle conceivable, that their expression is also triggered

Fig 3 P4ha1, P4ha2, PDI and PLOD1, PLOD2, and procollagen

Ia mRNA in A7r5 cells after exposure to cobalt(II) chloride

(100 lmolÆL -1 ) (A) or to deferoxamine (100 lmolÆL -1 ) (B) for 12 h at

21% O 2 Data are means ± SEM of five experiments each *P < 0.05

vs control (21% O 2 ) Controls are the means of five experiments and

the average mRNA/b-actin mRNA ratio is set to 1 (dotted line).

Fig 4 P4ha1, P4ha2, PDI, PLOD1 and PLOD2 mRNA in mouse As4.1 cells after exposure to hypoxia (0.5% O 2 ), to deferoxamine (100 lmolÆL -1

) and to cobalt(II) chloride (100 lmolÆL -1

)(at 21%O 2 ) for 4.5 h of incubation Data are means ± SEM of five experiments each.

*P < 0.05 vs control (21% O 2 ) Controls are the means of five experiments and the average mRNA/b-actin mRNA ratio is set to 1 (dotted line).

Fig 5 P4ha1, P4ha2, PDI mRNA and procollagen Ia mRNA in Hepa1 (A) and in Hepa1C4 cells (B) after exposure to hypoxia (0.5% O 2 ) or to deferoxamine (100 lmolÆL -1

) at 21% O 2 Data are means ± SEM of five experiments each *P < 0.05 vs control (21% O 2 ) Controls are the means of five experiments and the average mRNA/b-actin mRNA ratio is set to 1 (dotted line).

Fig 2 Time course of P4ha1, P4ha2 mRNA (A) and PLOD1, PLOD2

mRNA (B) and PDI, procollagen Ia mRNA (C) in A7r5 cells after

exposure of the cells to 1% O 2 Data are means ± SEM of five

experiments *P < 0.05 hypoxia (1% O 2 ) vs normoxia (21% O 2 ).

Controls are the means of five experiments and the average

mRNA/b-actin mRNA ratio is set to 1 (dotted line).

by a disturbance of protein folding due to energy depletion

in the course of cellular hypoxia This so-called unfolded

protein response (UPR) can also be elicited by tunicamycin

at normal oxygen tensions [28], as shown in Fig 7

Tunicamycin gave a clear twofold increase of PDI mRNA,

a more moderate increase of the mRNAs for prolyl

hydroxylases, and did not increase the mRNA abundance

of the other enzymes

Discussion

Our data show that the expression of a functional cluster of hydroxylases enzymes crucially required for procollagen maturation and collagen fiber formation are regulated in concert by the tissue oxygen tension, in the way that they are up-regulated at low oxygen tensions, i.e hypoxia This observation thus confirms the previous notion about an increased prolyl hydroxylase activity in hypoxic tissues

in situ[10], as well as the up-regulation of P4ha1 mRNA and protein in response to hypoxia in cell culture [14] As to the induction of P4ha1 mRNA and protein our data obtained

in A7r5 cells are almost identical with regard to time course and to ability to stimulate to those reported by Takahashi and coworkers for fetal lung fibroblasts [14] As to the induction of PDI mRNA, our data are also in good accordance regarding the delayed time course and the differential ability to stimulate by hypoxia, iron chelation and cobalt with those reported by Tanaka and coworkers for cultured astrocytes [15] Our findings thus on the one hand fully support these previous findings and on the other hand extend them by far and set them in a more general context, as both a-subunits of P4h, PDI as the b-subunit of P4h [13] and the collagen procollagen lysyl hydroxylases PLOD1 and PLOD2 are oxygen regulated As these effects were seen in different mouse and rat cell lines, we infer that the up-regulation of the procollagen hydroxylases during hypoxia is a more general effect with physiological relevance

Such a concerted regulation of these key enzymes of collagen formation appears reasonable from a physiological point of view, as all of these enzymes use oxygen directly as

a common substrate and because the formation of collagen requires the coordinated activities of all the enzymes Such a common regulation of a functional cluster of genes by the oxygen tension has already been found for the enzymes involved in the glycolytic cascade [29] and also for the key players of angiogenesis [30]

Considering the parallel up-regulation of enzymes involved in collagen fiber formation raises the question of whether this up-regulation is physiologically primarily meant to increase collagen formation in hypoxic tissues,

or if it reflects more a compensatory change of the concentration of enzyme molecules to maintain a given normal hydroxylation rate at altered substrate (oxygen) concentrations (Fig 8) The explanation as a compensatory increase of gene expression was previously also presented for the increased expression of the endoplasmic oxido-reductase Ero1-L during hypoxia which transfers oxidizing equivalents onto PDI [27] Such a view would be supported

by the observation that the expression of the procollagen (Ia) gene itself was not regulated by the oxygen tension, which is also in accordance with data obtained by others [7]

As the genes for P4ha1, P4ha2, PDI, and PLOD 1,2 are localized on different chromosomes the question arises concerning the mechanisms underlying the orchestrated expression of these enzymes by the oxygen tension The findings that the effect of hypoxia on the gene expression of the hydroxylases was mimicked by the iron

Fig 6 P4ha1, P4ha2, PDI, PLOD1 and PLOD2 mRNA in mouse

embryonic fibroblasts with intact and with disrupted HIF-1a gene after

exposure to hypoxia (0.5% O 2 ) or to deferoxamine (100 lmolÆL-1) at

21%O 2 for 24 h Data are means ± SEM of five experiments each.

*P < 0.05 vs control (21% O 2 ) Controls are the means of five

experiments and the average mRNA/b-actin mRNA ratio is set to 1

(dotted line).

Fig 7 P4ha1, P4ha2, PDI, PLOD1, PLOD2, and procollagen I(a)

mRNA in mouse As4.1 cells after incubation with tunicamycin

(10 lgÆmL -1 ) for 24 h at 21% O 2 Data are means ± SEM of five

experiments each *P < 0.05 vs control (21% O 2 ) Controls are the

means of five experiments and the average mRNA/b-actin mRNA

ratio is set to 1 (dotted line).

chelator deferoxamine and the divalent cation cobalt,

suggest that these genes are under the control of the

hypoxia inducible transcription factor HIF HIF is a

heterotetramer consisting of an a- and a b-subunit [31]

The protein abundance of this protein dimer is inversely

related to the cellular tension, because the a- but not

b-subunit protein stability is dependent on the oxygen

tension, in the way that the a-subunit is more stable at low

oxygen tensions The reason for this behavior is an oxygen

dependent prolyl-hydroxylation of the a-subunit, which

finally directs the protein to proteasomal degradation [32]

The assumption that HIF could in fact be a main trigger of

the procollagen hydroxylases is further corroborated by the

findings that the stimulatory effect of hypoxia on gene

expression was absent in cells with a functional inactive HIF

or lacking the HIF-1a protein in general In fact, for the

P4ha1I the involvement of HIF in the activation of gene

expression during hypoxia has recently been directly

dem-onstrated [14] A search for the HIF-binding consensus

sequence CGTG revealed six, six, two, nine and 10

theoretical HIF binding sites within the first 1 kb of the

5¢-promoter region of mouse P4ha1, P4ha2, PLOD1,

PLOD, and PDI, respectively

Although prolyl hydroxylation is a critical event for both

procollagen triple helix stabilization on the one hand and

for the stability of HIF-1a protein, different prolyl

hydroxylases appear to be required for these processes

HIF-a prolyl hydroxylation is managed by PHD-1, -2 and

-3 [33,34], whilst procollagen prolylhydroxylation is

performed by P4h [13], which does not accept HIF-a as

a substrate [31] Interestingly, the expressions of PHD-3

[35,36] and eventually of PHD-2 itself are also oxygen

sensitive [35,36] They are up-regulated by hypoxia by a process critically involving HIF, which in turn is also the substrate of PHD-2 and PHD-3 Thus, PHD-2, PHD-3 and P4h expression appear to be subject to a common control by oxygen, whilst the expression of PHD-1 is not The physiological meaning of this differential regulation of PHD-gene expression remains to be clarified

In spite of the similar regulation of PHD-2, PHD-3 and P4h expression by oxygen, not only the protein target but also the intracellular localization is different between the two groups of enzymes Whilst PHD-1, -2 and -3 are mainly cytosolic and nuclear proteins [37], P4h is like the lysyl hydroxylases PLOD1 and -2, being localized within the endoplasmic reticulum [13,38] This localization could

be of some interest, as HIF-regulated genes, as identified

so far, encode mainly for cytosolic or for secreted proteins [28,39] Constituents of the endoplasmic reticulum as being HIF-regulated have not yet been frequently reported [39] We have recently obtained evidence that the expres-sion of endoplasmic oxidoreductase Ero1-L, which oxid-izes PDI, is also controlled by HIF [27] Given the conjunction of PDI with PDH-4and the conjunction of PDI with Ero1-L as an essential oxidizing enzyme of PDI, there arises the concept a network of endoplasmic enzymes that mediate oxygen dependent reactions and that are in turn regulated by the oxygen tension in an inverse fashion most likely regulated by the transcription factor HIF-1

It must be considered in this context that the expression

of endoplasmic proteins with folding or chaperone function might also be indirectly triggered by cellular hypoxia through the UPR [40] induced by cellular energy depletion [41,42] We have addressed this issue therefore by investi-gating the influence of the UPR for the expression of the procollagen hydroxylases With the exception of PDI, which

is known to be induced by the UPR [41], however, none of the other enzymes was relevantly induced by the UPR, supporting the assumption that they are more directly triggered by HIF

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