In situ hybridisation of a large repertoire of muscle-specific transcripts in fish larvae: the new superficial slow-twitch fibres exhibit characteristics of fast-twitch differentiation.

Much of the present information on muscle differentiation in fish concerns the early embryonic stages. To learn more about the maturation and the diversification of the fish myotomal fibres in later stages of ontogeny, we investigated, by means of in situ hybridisation, the developmental expression of a large repertoire of muscle-specific genes in trout larvae from hatching to yolk resorption. At hatching, transcripts for fast and slow muscle protein isoforms, namely myosins, tropomyosins, troponins and myosin binding protein C were present in the deep fast and the superficial slow areas of the myotome, respectively. During myotome expansion that follows hatching, the expression of fast isoforms became progressively confined to the borders of the fast muscle mass, whereas, in contrast, slow muscle isoform transcripts were uniformly expressed in all the slow fibres. Transcripts for several enzymes involved in oxidative metabolism such as citrate synthase, cytochrome oxidase component IV and succinate dehydrogenase, were present throughout the whole myotome of hatching embryos but in later stages became concentrated in slow fibre as well as in lateral fast fibres. Surprisingly, the slow fibres that are added externally to the single superficial layer of the embryonic (original) slow muscle fibres expressed not only slow twitch muscle isoforms but also, transiently, a subset of fast twitch muscle isoforms including MyLC1, MyLC3, MyHC and myosin binding protein C. Taken together these observations show that the growth of the myotome of the fish larvae is associated with complex patterns of muscular gene expression and demonstrate the unexpected presence of fast muscle isoform-expressing fibres in the most superficial part of the slow muscle.

Muscle growth patterns and regulation during fish ontogeny.

In fish, the skeletal muscle of the trunk and the tail derives from the somites which form in the paraxial mesoderm in a rostro-caudal sequence. The development of the fish myotome begins with the onset of myogenic regulatory factors expression and continues with the formation of a distinct superficial layer of slow muscle fibres that covers a bulk of fast muscle fibres located in the deep portion of the myotome. Muscle fibres of the slow-twitch lineage originate in fish embryos from adaxial cells, a distinct subpopulation of the paraxial mesoderm that flanks the notochord. During the early maturation of the somite these adaxial cells migrate away from the notochord towards the lateral part of the somite where they form the superficial slow fibres. Lateral presomitic cells that remain deep in the myotome differentiate into fast muscle fibres. Morphogens of the hedgehog family secreted by the notochord have a pivotal role in inducing the slow-twitch lineage. In late embryos, additional fibres are added from discrete germinal zones situated at the ventral and dorsal extremes of the developing myotome. This regionalised process has been termed "stratified hyperplasia." In fish which grow to a large final size this is followed by a mosaic hyperplastic process that leads to the formation of new fibres throughout the whole myotome. Current knowledge about the endocrine and autocrine factors that potentially regulate the proliferation and the differentiation of muscle cells within the embryonic and larval fish myotome is reviewed.

Muscle fiber differentiation in fish embryos as shown by in situ hybridization of a large repertoire of muscle-specific transcripts.

Skeletal muscles are composed of different fiber types, largely defined by differential expression of protein isoforms involved in myofibrillogenesis or metabolism. To learn more about the gene activations that underlie the differentiation and the diversification of embryonic fish myotomal fibers, we investigated the developmental expression of 25 muscle genes in trout embryos by in situ hybridization of muscle-specific transcripts. The earliest event of muscle differentiation, at approximately the 25-somite stage, was the expression of a variety of muscle-specific genes, including slow-twitch and fast-twitch muscle isoforms. The activation of these muscle genes started in the deep somitic domain, where the slow muscle precursors (the adaxial cells) were initially located, and progressively spread laterally throughout the width of the myotome. This mediolateral progression of gene expression was coordinated with the lateral migration of slow adaxial cells, which specifically expressed the slow myosin light chain 1 and the SLIM1/FHL1 genes. Subsequently, the fast and slow skeletal muscle isoforms precociously expressed in the course of the mediolateral wave of muscle gene activation became down-regulated in the superficial slow fibers and the deep fast fibers, respectively. Finally, several muscle-specific genes, including troponins, a slow myosin-binding protein C, tropomodulins, and parvalbumin started their transcription only in late embryos. Taken together, these findings show in fish embryos that a common myogenic program is triggered in a mediolateral progression in all muscle cells. The acquisition of the slow phenotype involves the additional activation of several slow-specific genes in migrating adaxial muscle cells. These events are followed by sequential gene activations and repressions in fast and slow muscle cells.

Expression patterns of collagen I (alpha1) encoding gene and muscle-specific genes reveal that the lateral domain of the fish somite forms a connective tissue surrounding the myotome.

Somites are repeated, epithelial structures that are derived from the unsegmented paraxial mesoderm located lateral to the notochord. In higher vertebrates, somites differentiate into a sclerotome that subsequently forms the vertebrae and the ribs and into a dermomyotome that gives rise to a myotome, from which arises the skeletal muscle, and to a dermatome, from which arises the dermis. Fish somites have been shown to produce a sclerotome and a myotome, but very little is known regarding their participation in the formation of connective tissues, especially at the junction between the epidermis and the myotome. To investigate the formation of connective tissues in fish somites, we have examined the expression pattern of the collagen I (alpha1) chain. As somitogenesis proceeds rostrocaudally, collagen I (alpha1) expression marks the sclerotomal cells and delineates the formation of the vertebrae. Surprisingly, after the completion of the segmentation, transcript for the collagen I (alpha1) chain appeared in a distinct epithelial-like monolayer situated at the periphery of the developing somite facing the surface epidermis. This epithelial monolayer of somitic cells that covered the superficial slow muscle cells, did not express the myogenic transcriptional regulator myogenin and was devoid of contractile filament. As the somite increased in size, these collagen-expressing epithelial cells flattened, forming a thin cellular layer underlying the epidermis and recovering the lateral surface of the myotome. In conclusion, the lateral domain of the fish somite forms a distinct epithelial cell layer sharing many characteristics with amniote dermatome.

Effect of refeeding on IGFI, IGFII, IGF receptors, FGF2, FGF6, and myostatin mRNA expression in rainbow trout myotomal muscle.

Fish endure long periods of fasting and demonstrate an extensive capacity for rapid and complete recovery after refeeding. The underlying mechanisms through which nutrient intake activates an increase in somatic growth and especially in muscle growth is poorly understood. In this study we examined the expression profile of major muscle growth regulators in trout white muscle 4, 12, and 34 days after refeeding, using real-time quantitative RT-PCR. Mean insulin-like growth factor I (IGFI) mRNA level in muscle increased dramatically 8- and 15-fold, 4 and 12 days, respectively, after refeeding compared to fasted trout. This declined thereafter. Conversely, only a weak but gradual increase in mean insulin-like growth factor II (IGFII) mRNA level was observed during refeeding. Inversely to IGFI, mean IGF receptor Ia (IGFRIa) mRNA level declined after ingestion of food. In contrast, IGF receptor Ib (IGFRIb) mRNA level was not affected by refeeding. Mean fibroblast growth factor 2 (FGF2) mRNA level increased by 2.5-fold both 4 and 12 days after refeeding, whereas fibroblast growth factor 6 (FGF6) and myostatin mRNA levels were unchanged. Subsequent to IGFI and FGF2 gene activation, an increase in myogenin mRNA accumulation was observed at 12 days post-refeeding suggesting that an active differentiation of myogenic cells succeeds their proliferation. In conclusion, among the potential growth factors we examined in this study, IGFI and FGF2 were identified as candidate genes whose expression may contribute to muscle compensatory growth induced by refeeding.

Two myostatin genes are differentially expressed in myotomal muscles of the trout (Oncorhynchus mykiss).

Myostatin (GDF8) has been shown to be a major genetic determinant of skeletal muscle growth in mammals. In this study, we report the cloning of two trout cDNAs that encode two distinct myostatin-related proteins. The presence in this fish species of two myostatin genes (Tmyostatin 1 and Tmyostatin 2) probably results from the recent tetraploïdisation of the salmonid genome. A comparative reverse-transcriptase-linked polymerase chain reaction assay revealed that Tmyostatin 1 mRNA was present ubiquitously in trout tissues, while Tmyostatin 2 mRNA expression was restricted to muscle and brain. In developing muscle, Tmyostatin 1 expression was observed in eyed-stage embryos well before hatching, whereas Tmyostatin 2 was expressed only in free-swimming larvae. In myotomal muscle from adult animals, Tmyostatin 1 mRNA accumulation was similar in both slow- and fast-twitch fibres, and its concentration did not change during the muscle wasting associated with sexual maturation. In contrast, Tmyostatin 2 mRNA accumulated predominantly in slow-twitch fibres, and its concentration decreased dramatically in wasting muscles from maturing animals. This work shows that two distinct myostatin genes are present in the trout genome. Furthermore, it indicates that these two trout myostatin genes (i) exhibit a distinct expression pattern in muscle and non-muscle tissues and (ii) are not upregulated during the muscle wasting that accompanies sexual maturation.

Red and white muscle development in the trout (Oncorhynchus mykiss) as shown by in situ hybridisation of fast and slow myosin heavy chain transcripts.

The axial muscle of most teleost species consists of a deep bulk of fast-contracting white fibres and a superficial strip of slow-contracting red fibres. To investigate the embryological development of fast and slow muscle in trout embryos, we carried out single and double in situ hybridisation with fast and slow myosin heavy chain (MyHC)-isoform-specific riboprobes. This showed that the slow-MyHC-positive cells originate in a region of the somite close to the notochord. As the somite matures in a rostrocaudal progression, the slow-MyHC-positive cells appear to migrate radially away from the notochord to the lateral surface of the myotome, where they form the superficial strip of slow muscle. Surprisingly, the expression pattern of the fast MyHC showed that the differentiation of fast muscle commences in the medial domain of the somite before the differentiation and migration of the slow muscle precursors. Later, as the differentiation of fast muscle progressively spreads from the inside to the outside of the myotome, slow-MyHC-expressing cells become visible medially. Our observations that the initial differentiation of fast muscle takes place in proximity to axial structures and occurs before the differentiation and migration of slow muscle progenitors are not in accord with the pattern of muscle formation in teleosts previously described in the zebrafish Danio rerio, which is often used as the model organism in fishes.

Regulation and functions of myogenic regulatory factors in lower vertebrates.

The transcription factors of the MyoD family have essential functions in myogenic lineage determination and muscle differentiation. These myogenic regulatory factors (MRFs) activate muscle-specific transcription through binding to a DNA consensus sequence known as the E-box present in the promoter of numerous muscle genes. Four members, MyoD, myogenin, myf5 and MRF4/herculin/myf6, have been identified in higher vertebrates and have been shown to exhibit distinct but overlapping functions. Homologues of these four MRFs have also been isolated in a variety of lower vertebrates, including amphibians and fish. Differences have been observed, however, in both the expression patterns of MRFs during muscle development and the function of individual MRFs between lower and higher vertebrates. These differences reflect the variety of body muscle formation patterns among vertebrates. Furthermore, as a result of an additional polyploidy that occurred during the evolution of some amphibians and fish, MyoD, myogenin, myf5 and MRF4 may exist in lower vertebrates in two distinct copies that have evolved separately, acquiring specific roles and resulting in increased complexity of the myogenic regulatory network. Evidence is now accumulating that many of the co-factors (E12, Id, MEF2 and CRP proteins) that regulate MRF activity in mammals are also present in lower vertebrates. The inductive signals controlling the initial expression of MRFs within the developing somite of lower vertebrate proteins are currently being elucidated.

Developmental program expression of myosin alkali light chain and skeletal actin genes in the rainbow trout Oncorhynchus mykiss.

We have isolated MLC1(F) (tMLC1(F)), MLC3(F) (tMLC3(F)) and skeletal actin cDNAs from the teleost Oncorhynchus mykiss. Sequence analysis indicates that tMLC1(F) and tMLC3(F) are not produced from differentially spliced mRNAs as reported in avians and rodents but are encoded by different genes. Results from RNase protection analysis showed that the corresponding transcripts are expressed in fast skeletal muscles. Whole-mount in situ hybridisation revealed distinct expression patterns of the myosin alkali light chains and skeletal actin genes during skeletal muscle development in the embryo.

Differential expression of two nonallelic MyoD genes in developing and adult myotomal musculature of the trout (Oncorhynchus mykiss).

Previously we identified two nonallelic MyoD encoding genes in the rainbow trout. These two MyoD genes (TMyoD and TMyoD2) were duplicated during the tetraploidization of the salmonid genome. In this study we show that TMyoD and TMyoD2 exhibit a distinct spatiotemporal pattern of expression that defines discrete cell populations in the developing somite. TMyoD expression is first detected in the mid-gastrula on either side of the elongating embryonic shield. During the anterior-to-posterior wave of somite formation the TMyoD transcript is initially present in adaxial cells of both the presomitic mesoderm and the forming somites. A lateral extension of TMyoD expression occurs only when the myotomes acquire their characteristic chevron shape pointing rostrally. By contrast, the initial expression of TMyoD2 occurs in somites that have already formed and is limited to the posterior compartment of somites. Further, in postlarval trout we observed a differential expression of TMyoD and TMyoD2 genes in muscle fibers with differing phenotype. Collectively, these data provide evidence that the two trout MyoD encoding genes have evolved to become functionally different. A comparison of the expression patterns of the two trout MyoD genes with that of myogenin allowed us to position them in the regulatory pathway leading to muscle differentiation.

Expression of a cysteine-rich protein (CRP) encoding gene during early development of the trout.

Members of the cysteine-rich protein (CRP) define a subclass of LIM-only proteins implicated mainly in muscle differentiation. Until now, very little is known concerning the expression of CRP encoding genes during vertebrate development. We describe here the isolation of a trout (Oncorhynchus mykiss) gene encoding a cysteine-rich protein (TCRP) and the pattern of its mRNA accumulation during embryogenesis, focusing on somitogenesis. TCRP encodes a putative protein with two LIM domains linked to a short glycine-rich region that displays 86%, 76%, 67% identity with chicken CRP2, CRP1 and MLP/CRP3 proteins, respectively. Whole-mount in situ hybridisation showed that TCRP transcript is first detected just before somitogenesis in the paraxial mesoderm, while it is absent in the axial structures. During somitogenesis, the expression of TCRP was observed caudally in the elongating presomitic mesoderm and in the last formed somites. The labelling for TCRP was found to fade as the somites mature. At the end of the somitogenesis, TCRP transcripts accumulation was restricted to pronephros and bronchial arches.

Identification of a fibroblast growth factor 6 (FGF6) gene in a non-mammalian vertebrate: continuous expression of FGF6 accompanies muscle fiber hyperplasia.

FGF6, a member of the fibroblast growth factor (FGF) family, is specifically expressed in developing skeletal muscle and may participate in muscle maintenance and regeneration. Until now, no convincing evidence for the existence of an FGF6 gene in non-mammalian vertebrates has been put forward. Only a hybrid growth factor containing features characteristic of both FGF4 and FGF6 has been identified in frogs and chickens, suggesting that the step of duplication which created FGF4 and FGF6 took place with the emergence of mammals. In this study, we report the isolation and characterization of a genomic clone encoding the trout (Oncorhynchus mykiss) fibroblast growth factor 6 (TFGF6). An initial cDNA clone was generated by PCR amplification using degenerate oligo primers corresponding to a conserved region of protein found in the mouse and human homologs. The screening of a genomic library with the cloned PCR product led to the isolation of a clone composed of three exons encoding a putative protein of 206 amino acids which exhibits a potential signal peptide and shows 64.6 and 63.6% similarity with mouse and human FGF6, respectively (77% over the carboxy two-thirds of the protein) and only 46.5% similarity with mouse and human FGF4 (62% over the carboxy two-thirds of the protein). The splice position of the three exons was found to be analogous to the human and mouse FGF6 and the start translation site of TFGF6 was preceded by a long stretch of nucleotides that is highly and specifically conserved in mammalian FGF6. Furthermore, a comparative reverse transcriptase-linked PCR assay revealed that the expression pattern of TFGF6 is close to that of mammals, TFGF6 transcripts being present in muscle (fast-twitch and to a lesser extent slow-twitch fibers), heart, testis and brain. Interestingly, the prolonged phase of muscle fiber hyperplasia which occurs in trout is accompanied by the lasting expression of TFGF6 up to the adult stage suggesting that TFGF6 may participate in the continuous generation of muscle fibers within the myotomal musculature of post larval animals.

Identification in a fish species of two Id (inhibitor of DNA binding/differentiation)-related helix-loop-helix factors expressed in the slow oxidative muscle fibers.

Helix-loop-helix (HLH) proteins related to the inhibitor of DNA binding/differentiation (Id) serve as general antagonists of cell differentiation. They lack a basic DNA-binding domain and are thought to function in a dominant negative manner by sequestering basic HLH (bHLH) transcription factors that are involved in cell determination and differentiation. Four Id-encoding genes have been shown in mammals, they have a distinct pattern of expression suggesting different functions for each member in different cell lineage. In this study we describe the identification and cloning of two trout cDNAs which encode helix-loop-helix proteins showing a high degree of similarity with mammalian Id family members. One cDNA encodes a trout putative Id1 protein (TId1) that is 63% identical to the human Id1 protein over the entire length and 78% identical within the HLH region. The other cDNA encodes a trout putative Id2 protein (TId2) that shows 82% identity to the human Id2 protein and only one change that is conservative over the HLH region. In the 3' untranslated region, TId2 mRNA exhibits 16 nucleotides upstream from the AATAAA site, a palindromic sequence similar to the cytoplasmic polyadenylation element (CPE) which is also present in Id2 and Id3 mRNAs from mammals and in XIdx/XIdI mRNA from Xenopus. In the fish, TId1 and TId2 are expressed in a tissue-specific manner, with slightly different patterns. During myogenesis, TId1 and TId2 are highly expressed in the myotomal musculature of fish embryos and of early alevins but are down-regulated in that of late alevins. In muscle from juveniles and adults, TId1 and TId2 transcripts are abundant in the slow oxidative fibers while they are absent in the fast glycolytic fibers. This expression pattern suggests that Id genes play a role in the regulation of muscle fiber phenotype in addition to controlling early myogenesis. On the whole, the identification of two HLH-Id encoding genes in a major taxonomic group like teleosts, suggests an early divergence of Id genes in vertebrate evolution. The observation that Id transcripts are present selectively in the slow muscle reveals that their expression is more complicated than previously appreciated.

Genome of the rainbow trout (Oncorhynchus mykiss) encodes two distinct muscle regulatory factors with homology to myoD.

Previously we identified a trout myogenic factor related to MyoD. We now present a cDNA encoding a novel trout myogenic factor (TMyoD2) expressed in embryonic muscle. Nucleotide analysis and amino acid comparison showed that this cDNA encodes a MyoD-like protein of 275 amino acids that is distinct but related to TMyoD with 78% identity over the entire length. The protein sequence conservation between TMyoD2 and TMyoD was calculated to be 90% within the basic/helix-loop-helix domain that is involved in DNA binding and heterooligomerisation. At the nucleotide level, comparison of TMyoD with TMyoD2 reveals that the translated regions are flanked by highly divergent 3' and 5' ends. The substantial differences observed at translated and especially untranslated regions strongly suggest that TMyoD and TMyoD2 mRNA originate from different loci. The TMyoD and TMyoD2 mRNA are likely transcribed from two distinct genes which were duplicated during the tetraploïdization of the salmonid genome.

A gene with homology to myogenin is expressed in developing myotomal musculature of the rainbow trout and in vitro during the conversion of myosatellite cells to myotubes.

We report the cloning of a new trout myogenic cDNA which encodes helix-loop-helix protein homologous to the myogenic factor myogenin. Northern analyses indicate that trout myogenin (Tmyogenin) transcripts accumulate in large amounts in the myotomal musculature of embryos and frys. In adults, transcripts concentrate within the thin lateral layer of red (slow oxydative) muscle fibres. They are present only in low amounts in white (fast glycolytic) muscle fibres which constitute the major part of the trunk musculature. Using an in vitro myogenesis system, we observed that the trout myogenin encoding gene is not activated until myosatellite cells fuse to generate multinucleated myotubes, indicating that Tmyogenin lies downstream of muscle determination factors. All these observations show that in a major taxinomic group like teleosts, a gene with homology to myogenin exists. Its activation during myogenesis suggests that it acts as a major developmental regulator of muscle differentiation.

Identification of a muscle factor related to MyoD in a fish species.

We have isolated the cDNA encoding a myogenic factor expressed in embryonic trout muscle by hybridization with a Xenopus MyoD cDNA. Nucleotide sequence analysis and amino acid comparison showed that this cDNA called TMyoD encodes a polypeptide of 276 amino acids with 70% identity to the entire Xenopus MyoD protein and 92% identity within the basic and myc-like region. Results from Northern blotting showed that the corresponding transcript is expressed both in adult and embryonic skeletal musculature and in an in vitro myogenesis system, but is undetectable in cardiac and smooth muscles and in non muscle tissues.

Distribution and origin of the basement membrane component perlecan in rat liver and primary hepatocyte culture.

Basement membranes contain three major components (ie collagen IV, laminin, and the heparan sulfate proteoglycan termed perlecan). Although the distribution and origin of both collagen IV and laminin have been well documented in the liver, perlecan has been poorly investigated, so far. We have studied the distribution and cellular origin of perlecan in rat livers in various conditions as well as in hepatocyte primary culture. By immunolocalization in both adult and 18-day-old fetal liver, perlecan was found in portal spaces, around central veins, and throughout the lobule. Immunoelectron microscopy revealed its presence at the level of basement membranes surrounding bile ducts and blood vessels, and in the space of Disse discontinuously interacting with hepatocyte microvilli. Precursors of perlecan were detected in the rough endoplasmic reticulum of bile duct cells and both vascular and sinusoidal endothelial cells. Both hepatocytes and Ito cells were negative. Northern-blot analysis confirmed the lack of appreciable expression of perlecan in hepatocytes isolated from either fetal or adult livers. In 18-month-diethylnitrosamine-treated rat liver, perlecan was abundant in neoplastic nodules. Electron microscopic investigation revealed an almost continuous layer of perlecan in the space of Disse and intracellular staining in sinusoidal endothelial cells, only. Perlecan mRNAs were detectable in malignant nodules, and absent in hepatocytes from nontumorous areas. Hepatocytes expressed high levels of perlecan mRNAs only when put in culture. This expression was reduced in conditions that allow improvement of hepatocyte survival and function (ie addition of corticoids, dimethylsulfoxide or nicotinamide to the medium, or in coculture with liver epithelial cells from biliary origin). Immunolocalization by light and electron microscopy showed that deposition of the proteoglycan occurred in coculture, in basement membranelike structures located around hepatocyte cords. In vitro attachment assay of hepatocytes on purified perlecan substrate indicated that these cells may interact with the proteoglycan through integrins which belong to the beta 1 family. These data suggest that deposition of perlecan in the space of Disse requires cellular cooperation. This article on perlecan, the third major component of hepatic basement membranes, shows a unique cellular origin in the liver and, as found for both collagen IV and laminin, an expression in adult hepatocytes when place in culture.

Distribution and cellular origin of collagen VI during development and in cirrhosis.

Collagen VI is a ubiquitous microfibrillar collagen that forms a network in most interstitial connective tissues, including soft organs and cartilage. The extracellular and intracellular distribution of collagen VI in human liver was studied by light and electron microscopy using the indirect immunoperoxidase method. In normal adult liver, collagen VI was seen mainly in portal spaces and formed a continuous layer in the sinusoids. Fetal liver contained more of collagen VI in the sinusoid than newborn and adult livers. In alcoholic fibrotic and cirrhotic livers, collagen VI antibodies intensely stained fibrous septa that invaded the lobule. Immunoelectron microscopy on normal liver showed that collagen VI antibodies labeled microfibrillar material and occasionally the surface of cells including hepatocytes. In both perinatal and fibrotic livers, electron-dense deposits were abundant in the space of Disse, intensely staining fibrils located around bundles of banded collagen. In both normal and fibrotic adult livers, collagen VI was abundant in the rough endoplasmic reticulum of Ito cells, while hepatocytes were constantly negative. In fetal livers, hepatocytes also contained collagen VI. These results suggest that collagen VI is a major constituent of the hepatic extracellular matrix. Furthermore, the cellular sources of collagen VI appear to be different in adult and developing livers.

Differential expression of laminin chains in hepatic lipocytes.

The lipocyte is an important source of laminin in the normal liver. We have investigated the expression of the 3 chains of laminin in isolated rat lipocytes. Both B1 and B2 chains, but not A, were found in medium from 5-day-old lipocyte primary cultures by immunoblotting and immunoprecipitation of 35S-labeled proteins after reducing SDS-polyacrylamide gel electrophoresis. An additional polypeptide of Mr = 380,000 was identified by immunoprecipitation. Under non-reducing conditions only one Mr = 900,000 band was revealed. High levels of B1 and B2 mRNAs were also demonstrated in 5-day-old cultured lipocytes while at the time of seeding, only B2 chain mRNAs were clearly detectable. A chain mRNA was constantly absent. These results suggest that lipocytes produce a variant form of laminin in primary culture and that the Mr = 380,000 polypeptide could be unrelated to the A chain of laminin.

Cellular sources of matrix proteins in experimentally induced cholestatic rat liver.

Collagens (I, III, and IV), fibronectin, and laminin were localized using the indirect immunoperoxidase technique 14 days after bile duct ligation, i.e., when extensive fibrosis and numerous neoformed bile ducts were observed. Extensive fibrous septa in enlarged portal spaces were stained for collagens I, III and IV, fibronectin, and laminin. Collagen IV and laminin were abundant around proliferative bile ducts. In addition, collagen IV was nearly continuous in the sinusoids. At the ultrastructural level, antigens were localized in the endoplasmic reticulum of several liver cell types. In portal spaces, bile duct cells and cells that form the transitional canal of Hering were strongly labelled for basement membrane components, particularly laminin, but not for collagens I and III and fibronectin, which were abundant in fibroblast-like cells. Inside the lobule, only Ito cells and, to a lesser extent, endothelial cells contained collagens, fibronectin, and laminin. Ito cells were found to be heavily stained for collagens III and IV, and laminin. Except for fibronectin, which was always abundant, precursors of extracellular matrix proteins were only slightly detectable in the endoplasmic reticulum of some hepatocytes, particularly those located close to altered areas. This study demonstrates that experimental extrahepatic cholestasis in the rat induces periportal fibrosis and continuous deposition of collagen IV in the sinusoids. Several cell types participate in the formation of extracellular matrix components, particularly bile duct cells and Ito cells, with a possible involvement of hepatocytes, thus suggesting that cholestasis provokes changes in the pattern of matrix protein production in liver cells.