Stem cell properties and repopulation of the rat liver by fetal liver epithelial progenitor cells.

The potential of embryonal day (ED) 14 fetal liver epithelial progenitor (FLEP) cells from Fischer (F)344 rats to repopulate the normal and retrorsine-treated liver was studied throughout a 6-month period in syngeneic dipeptidyl peptidase IV (DPPIV-) mutant F344 rats. In normal liver, FLEP cells formed: 1) hepatocytic clusters ranging in size up to approximately 800 to 1000 cells; 2) bile duct structures connected to pre-existing host bile ducts; and 3) mixed clusters containing both hepatocytes and bile duct epithelial cells. Liver repopulation after 6 months was moderate (5 to 10%). In retrorsine-treated liver, transplanted cells formed large multilobular structures containing both parenchymal and bile duct cells and liver repopulation was extensive (60 to 80%). When the repopulating capacity of ED 14 FLEP cells transplanted into normal liver was compared to adult hepatocytes, three important differences were noted: 1) FLEP cells continued to proliferate at 6 months after transplantation, whereas adult hepatocytes ceased proliferation within the first month; 2) both the number and size of clusters derived from FLEP cells gradually increased throughout time but decreased throughout time with transplanted mature hepatocytes; and 3) FLEP cells differentiated into hepatocytes when engrafted into the liver parenchyma and into bile epithelial cells when engrafted in the vicinity of the host bile ducts, whereas adult hepatocytes did not form bile duct structures. Finally, after transplantation of ED 14 FLEP cells, new clusters of DPPIV+ cells appeared after 4 to 6 months, suggesting reseeding of the liver by transplanted cells. This study represents the first report with an isolated fetal liver epithelial cell fraction in which the cells exhibit properties of tissue-determined stem cells after their transplantation into normal adult liver; namely, bipotency and continued proliferation long after their transplantation.

Cell transplantation causes loss of gap junctions and activates GGT expression permanently in host liver.

Cell transplantation into hepatic sinusoids, which is necessary for liver repopulation, could cause hepatic ischemia. To examine the effects of cell transplantation on host hepatocytes, we transplanted Fisher 344 rat hepatocytes into syngeneic dipeptidyl peptidase IV-deficient rats. Within 24 h of cell transplantation, areas of ischemic necrosis, along with transient disruption of gap junctions, appeared in the liver. Moreover, host hepatocytes expressed gamma-glutamyl transpeptidase (GGT) extensively, which was observed even 2 years after cell transplantation. GGT expression was not associated with alpha-fetoprotein activation, which is present in progenitor cells. Increased GGT expression was apparent after transplantation of nonparenchymal cells and latex beads but not after injection of saline, fragmented hepatocytes, hepatocyte growth factor, or turpentine. Some host hepatocytes exhibited apoptosis, as well as DNA synthesis, between 24 and 48 h after cell transplantation. Changes in gap junctions, GGT expression, DNA synthesis, and apoptosis after cell transplantation were prevented by vasodilators. The findings indicated the onset of ischemic liver injury after cell transplantation. These hepatic perturbations must be considered when transplanted cells are utilized as reporters for biological studies.

Identification of differentially expressed genes in epithelial stem/progenitor cells of fetal rat liver.

Differentially expressed cDNA clones from fetal rat liver were isolated using suppression subtractive hybridization, combined with an efficient screening strategy. Approximately 30,000 clones were screened, yielding 643 genes whose expression was induced, of which 201 clones were distinct and 68 represented ESTs or newly discovered genes of unknown function. Based on their expression patterns in different organs, fetal liver, liver regeneration models, and gut epithelial progenitor cell lines, the subtracted clones presented in this work were placed into four categories: (1) hepatoblast-specific genes; (2) hematopoietic cell-specific genes; (3) genes expressed in hepatoblasts, in hematopoietic cells, and at varying levels in other tissues; and (4) genes overexpressed in fetal liver, in models of activation of liver progenitor cells, and in epithelial progenitor cell lines. Hepatoblast-specific clones and those representing genes induced during liver regeneration are under further study to define their specific function(s) in liver cell growth control and/or differentiation.

Proliferation and differentiation of fetal liver epithelial progenitor cells after transplantation into adult rat liver.

To identify cells that have the ability to proliferate and differentiate into all epithelial components of the liver lobule, we isolated fetal liver epithelial cells (FLEC) from ED 14 Fischer (F) 344 rats and transplanted these cells in conjunction with two-thirds partial hepatectomy into the liver of normal and retrorsine (Rs) treated syngeneic dipeptidyl peptidase IV mutant (DPPIV(-)) F344 rats. Using dual label immunohistochemistry/in situ hybridization, three subpopulations of FLEC were identified: cells expressing both alpha-fetoprotein (AFP) and albumin, but not CK-19; cells expressing CK-19, but not AFP or albumin, and cells expressing AFP, albumin, and cytokeratins-19 (CK-19). Proliferation, differentiation, and expansion of transplanted FLEC differed significantly in the two models. In normal liver, 1 to 2 weeks after transplantation, mainly cells with a single phenotype, hepatocytic (expressing AFP and albumin) or bile ductular (expressing only CK-19), had proliferated. In Rs-treated rats, in which the proliferative capacity of endogenous hepatocytes is impaired, transplanted cells showed mainly a dual phenotype (expressing both AFP/albumin and CK-19). One month after transplantation, DPPIV(+) FLEC engrafted into the parenchyma exhibited an hepatocytic phenotype and generated new hepatic cord structures. FLEC, localized in the vicinity of bile ducts, exhibited a biliary epithelial phenotype and formed new bile duct structures or were incorporated into pre-existing bile ducts. In the absence of a proliferative stimulus, ED 14 FLEC did not proliferate or differentiate. Our results demonstrate that 14-day fetal liver contains lineage committed (unipotential) and uncommitted (bipotential) progenitor cells exerting different repopulating capacities, which are affected by the proliferative status of the recipient liver and the host site within the liver where the transplanted cells become engrafted. These findings have important implications in future studies directed toward liver repopulation and ex vivo gene therapy.

Role of thyroid hormone in stimulating liver repopulation in the rat by transplanted hepatocytes.

Recently, we reported near-complete repopulation of the rat liver by transplanted hepatocytes using retrorsine (RS), a pyrrolizidine alkaloid that alkylates cellular DNA and blocks proliferation of resident hepatocytes, followed by transplantation of normal hepatocytes in conjunction with two-thirds partial hepatectomy (PH). Because two-thirds PH is not feasible for use in humans, in the present study, we evaluated the ability of thyroid hormone (triiodothyronine [T(3)]), a known hepatic mitogen, to stimulate liver repopulation in the retrorsine model. Because T(3) initiates morphogenesis in amphibians through a process involving both cell proliferation and apoptosis, we also determined whether apoptosis might play a role in the mechanism of hepatocyte proliferation induced by T(3). Following hepatocyte transplantation and repeated injections of T(3), the number of transplanted hepatocytes in the liver of RS-pretreated animals increased progressively to repopulate 60% to 80% of parenchymal cell mass in 60 days. We show further that T(3) treatment augments proliferation of normal hepatocytes, as evidenced by increased histone 3 mRNA and cyclin-dependent kinase 2 (cdk2) expression, and this is followed by apoptosis. These combined effects of T(3) lead to selective proliferation of transplanted hepatocytes in RS-pretreated rats, while endogenous hepatocytes, which are blocked in their proliferative capacity by RS, mainly undergo apoptosis. Thus, T(3) can replace PH in the RS-based rat liver repopulation model and therefore represents a significant advance in developing methods for hepatocyte transplantation.

Differentiation-specific regulation of transgene expression in a diploid epithelial cell line derived from the normal F344 rat liver.

To establish the differentiation potential of progenitor cells, non-parenchymal epithelial cells from the F344 rat liver (FNRL cells) were studied. These cells reacted with the OV-6 antibody marker of oval cells, but were negative for hepatocyte markers (albumin, transferrin, glycogen, glucose-6-phosphatase, H4 antigen), biliary markers (gamma glutamyl transpeptidase, cytokeratin-19), and alpha-fetoprotein, although exposure to sodium butyrate induced nascent albumin and alpha-fetoprotein mRNA transcription. When stably transduced, FNRL cells expressed a retroviral promotor-driven lacZ reporter in vitro, similar to transgene expression in hepatocyte-derived HepG2 cells. However, lacZ expression in FNRL cells was rapidly extinguished in intact animals, whereas the reporter remained active in HepG2 cells. Transplanted FNRL cells showed copious glucose-6-phosphatase expression; however, the cell differentiation programme remained incomplete, despite two-thirds partial hepatectomy, D-galactosamine treatment or bile duct ligation. Interestingly, lacZ expression resumed in cultures of FNRL cells explanted from recipients. Moreover, lacZ expression was down-regulated by gamma-interferon in FNRL cells, without affecting lacZ activity in HepG2 cells. The data indicate that although subpopulations of oval cells may not fully differentiate into mature hepatocytes, these cells might serve critical functions, such as glucose utilization, and help survival after liver injury. Also, introduced genes may be regulated in progenitor cells at multiple levels, including by interactions between regulatory sequences, differentiation-specific cellular factors, and extracellular signals; in vivo studies are thus especially important for analysing gene regulation in progenitor cells.

Restoration of serum albumin levels in nagase analbuminemic rats by hepatocyte transplantation.

Recently, we described a new strategy for hepatocyte transplantation, using retrorsine/partial hepatectomy (PH) in a DPPIV- mutant Fischer rat model. Treatment of rats with retrorsine, a pyrrolizidine alkaloid, blocks endogenous hepatocytes from proliferating, so that after exposure to this agent coupled with PH and hepatocyte transplantation, transplanted hepatocytes selectively repopulate the liver. In the present study, we determined whether this method of cell transplantation can restore biosynthetic and physiological function in the liver by transplanting normal hepatocytes into rats genetically deficient in albumin synthesis, the Nagase analbuminic rat (NAR). After hepatocyte transplantation, albumin mRNA and protein were identified in the liver by in situ hybridization and immunohistochemistry, respectively, and serum albumin levels were determined using sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), Western blot, and enzyme-linked immunosorbent assay (ELISA) methods. At 1 month posttransplantation, large clusters of cells expressing albumin mRNA and protein were identified in the liver, representing approximately 50% of hepatocytes for albumin mRNA and approximately 61% for protein. At 2 months' posttransplantation, cells expressing albumin mRNA represented approximately 77% of hepatocyte mass, and cells expressing albumin protein represented approximately 81% of total hepatocyte mass. Hepatocyte-transplanted NAR also exhibited normal or near-normal serum albumin levels (3.0 +/- 0.2 g/dL). High levels of serum albumin were sustained for the 2-month duration of experiments. These results demonstrate the ability of this protocol for hepatocyte transplantation to restore a major biosynthetic and physiological function of the liver, and suggest its potential use as a method to treat genetic-based or acquired liver diseases.

Liver regeneration and alpha-fetoprotein messenger RNA expression in the retrorsine model for hepatocyte transplantation.

Recently, we described a new model for hepatocyte transplantation with nearly total replacement of the liver by exogenous hepatocytes (E. Laconi et al., Am. J. Pathol., 153: 319-329, 1998). The model is based on the mitoinhibitory effect of the pyrrolizidine alkaloid retrorsine on hepatocytes in the resident liver while transplanted hepatocytes proliferate. In this study, we exploit this novel approach to address the important and controversial issue of whether hepatocytes, when proliferating extensively, undergo dedifferentiation and give rise to foci of undifferentiated hepatocytes. Genetically marked hepatocytes (isolated from normal Dipeptidyl peptidase IV+ Fischer 344 rats) were delivered intraportally (2 x 10(6) cells) into the liver of retrorsine-treated Dipeptidyl peptidase IV- mutant Fischer 344 rats in conjunction with partial hepatectomy. Transplanted hepatocytes were detected histochemically or immunohistochemically, and cell proliferation was studied by in situ hybridization for histone-3 mRNA. Expression of alpha-fetoprotein (AFP) mRNA, a marker of hepatocyte dedifferentiation, was also revealed by in situ hybridization. One day after partial hepatectomy and hepatocyte transplantation, endogenous hepatocytes and oval cells expanding in the liver expressed histone-3 mRNA (cells had entered S phase); 2 days later, transplanted hepatocytes and nonparenchymal cells also expressed histone-3 mRNA. Although the majority of endogenous hepatocytes did not divide and became arrested as quiescent megalocytes, the exogenous hepatocytes, as well as newly formed small hepatocytes, most probably derived from liver progenitor cells, underwent extensive proliferation. After 7-14 days, the nonparenchymal cells stopped proliferating, but transplanted hepatocytes and small endogenous hepatocytes continued to proliferate for 1 month, forming foci of dividing parenchymal cells. Although many of the hepatocytes in clusters were in S phase (histone-3 mRNA positive), none expressed AFP mRNA. In contrast, high expression of AFP mRNA was observed in proliferating oval and transitional cells, forming duct-like structures of cytokeratin-19-positive cells. From these studies, we conclude that hepatocyte proliferation in the adult liver is not associated with dedifferentiation.

Long-term, near-total liver replacement by transplantation of isolated hepatocytes in rats treated with retrorsine.

Genetically marked hepatocytes from dipeptidyl peptidase (DPP) IV+ Fischer 344 rats were transplanted into the liver of DPPIV- mutant Fischer 344 rats after a combined treatment with retrorsine, a pyrrolizidine alkaloid that blocks the hepatocyte cell cycle, and two-thirds partial hepatectomy. In female rats, clusters of proliferated DPPIV+ hepatocytes containing 20 to 50 cells/cluster, mostly derived from single transplanted cells, were evident at 2 weeks, increasing in size to hundreds of cells per cluster at 1 month and 1000 to several thousand cells per cluster at 2 months, representing 40 to 60% of total hepatocyte mass. This level of hepatocyte replacement remained constant for up to 1 year, the duration of experiments conducted. In male rats, liver replacement occurred more rapidly and was more extensive, with transplanted hepatocytes representing 10 to 15% of hepatocyte mass at 2 weeks, 40 to 50% at 1 month, 90 to 95% at 2 months, 98% at 4 months, and 99% at 9 months. Transplanted hepatocytes were integrated into the parenchymal plates, exhibited unique hepatic biochemical functions, and fully reconstituted a normal hepatic lobular structure. The extensive proliferation of transplanted cells in this setting of persistent inhibition of resident hepatocytes represents a new general model to study basic aspects of liver repopulation with potential applications in chronic liver disease and ex vivo gene therapy.

Differentiation of pancreatic epithelial progenitor cells into hepatocytes following transplantation into rat liver.

The ability to identify, isolate, and transplant progenitor cells from solid tissues would greatly facilitate the treatment of diseases currently requiring whole organ transplantation. In this study, cell fractions enriched in candidate epithelial progenitor cells from the rat pancreas were isolated and transplanted into the liver of an inbred strain of Fischer rats. Using a dipeptidyl dipeptidase IV genetic marker system to follow the fate of transplanted cells in conjunction with albumin gene expression, we provide conclusive evidence that, after transplantation to the liver, epithelial progenitor cells from the pancreas differentiate into hepatocytes, express liver-specific proteins, and become fully integrated into the liver parenchymal structure. These studies demonstrate the presence of multipotent progenitor cells in the adult pancreas and establish a role for the liver microenvironment in the terminal differentiation of epithelial cells of foregut origin. They further suggest that such progenitor cells might be useful in studies of organ repopulation following acute or chronic liver injury.

Transcription factor and liver-specific mRNA expression in facultative epithelial progenitor cells of liver and pancreas.

The pattern of mRNA expression for liver-specific proteins and liver-enriched transcription factors was studied in two models of facultative gut epithelial progenitor cells activation: D-galactosamine (GalN)-induced liver injury and dietary copper depletion leading to pancreatic acinar atrophy. After 5 weeks of copper deficiency (CuD), pancreatic acini of Fischer 344 rats underwent atrophy, associated with intense proliferation of small duct-like cells with oval-shaped nuclei. These cells resemble morphologically epithelial progenitor cells of the liver that proliferate after GalN administration. Activated pancreatic epithelial cells express mRNAs for liver-specific genes normally expressed in fetal liver, including alpha-fetoprotein, albumin, alpha-1 antitrypsin, glucose-6-phosphatase, and others, but not genes that are turned on after birth such as serine dehydratase, tyrosine aminotransferase, and multidrug resistance gene-1b. They express mRNAs for liver-enriched transcription factors including HNF-1 alpha, HNF-3 beta and gamma, HNF-4, and members of the CCAAT-enhancer binding protein (C/EBP) family. The only mRNA for a liver-enriched transcription factor not detected in the pancreas of CuD animals was HNF-3 alpha. Expression of HNF-3 alpha, beta, and gamma, and C/EBP-beta mRNA was highly activated in proliferating liver epithelial cells on days 2 and 3 after GalN injury. Increased expression of C/EBP-delta was observed first in the liver on day 1 after GalN administration and in the pancreas at 4 weeks after initiating CuD. We suggest that C/EBP-delta could be involved in the initial activation of epithelial progenitor cells and that HNF-3 alpha, beta, and gamma, and C/EBP-beta might participate in their maturation. We conclude further that pancreatic epithelial progenitor cells undertake differentiation through the hepatocyte lineage but cannot complete the differentiation program within the pancreatic milieu.

Activation, proliferation, and differentiation of progenitor cells into hepatocytes in the D-galactosamine model of liver regeneration.

Rat liver regeneration was studied from 24 hours to 8 days after a single intraperitoneal injection of D-galactosamine (GalN). Morphological changes in the liver were analyzed in parallel with sequential changes in expression of histone-3 mRNA (a marker of cell proliferation), fetal alpha-fetoprotein (AFP) mRNA and gamma-glutamyl transpeptidase (GGT) (markers of fetal hepatocytes), and albumin mRNA and glucose-6-phosphatase (G6Pase) (markers of adult hepatocytes). Proliferation of nonparenchymal epithelial cells (NPC), detected in situ by [3H]thymidine labeling or histone-3 mRNA expression, began after 24 hours primarily in the portal area around the bile ducts. After 2 days, histone-3 labelling intensity increased in rows and clusters of NPC which expanded from the portal zone and invaded into the parenchyma. On days 3 and 5, NPC expressing his-3 mRNA expanded further, forming pseudo-ducts and islet-like structures (NPC structures). Proliferating NPC were positive for GGT. Some GGT positive cells were also positive for the fetal form of AFP mRNA, which lagged behind GGT by 24 hours and peaked on day 5. On day 3, some cells with the appearance of NPC expressed albumin mRNA. Double label in situ hybridization for fetal AFP and albumin mRNAs and dual histochemistry for GGT and G6Pase showed simultaneous expression of these markers in NPC on day 5. Other cells expressing fetal AFP mRNA or GGT on day 5 had a morphological appearance between NPC and hepatocytes (transitional cells). Proliferation of hepatocytes began on day 2, reached maximum on day 5 and then declined. Proliferating hepatocytes did not express fetal AFP mRNA or GGT. These findings indicate that after GalN injury, the liver responds by activation of progenitor cells that proliferate and then differentiate into mature hepatocytes. Adult hepatocytes can also proliferate after GAlN injury, but these hepatocytes do not undergo dedifferentiation/redifferentiation during regeneration of the hepatic lobule.

Models for hepatic progenitor cell activation.

Activation of liver progenitor cells was studied in rat liver induced to regenerate after carbon tetrachloride (CCl4) or D-galactosamine (GalN) injury. A change in the concentration of histone-3 mRNA was used as a marker for cell proliferation and the fetal form of alpha-fetoprotein (AFP) mRNA as a marker for fetal hepatoblasts. gamma-Glutamyltranspeptidase (GGT) and glutathione-S-transferase P were used as markers for activation of putative liver progenitor cells. After CCl4 administration, the proliferative response was high but confined primarily to parenchymal cells. No changes in the relative expression of albumin, glutathione-S-transferase P or insulin-like growth factor-II were observed. On the other hand, the level of AFP mRNA was increased modestly and predominantly in the nonparenchymal cell (NPC) fraction. After GalN administration, proliferation of NPC began within 24 hr, primarily in the portal area around the bile ducts. Activated cells were bile "duct-like" in appearance, had scant cytoplasm, and a pale, oval-shaped nucleus. On Day 2, they formed rows and clusters, expanding from the portal zone and invading the parenchyma, as well as proliferating in regions of focal necrosis. On Days 3 and 5, NPC expressing histone-3 mRNA expanded further, forming pseudoducts and islet-like structures (NPC structures) throughout the hepatic lobule. Proliferating NPC were positive for GGT. Some GGT-positive cells on Days 3 and 5 were also positive for fetal AFP mRNA. Expression of fetal AFP mRNA lagged behind that of GGT by 24 hr, was highest on Day 5, and then declined. Expression of albumin mRNA and glucose 6-phosphatase decreased during the first 48 hr after GalN administration and then resumed. These findings indicate that after GalN injury, the liver responds with activation of putative progenitor cells that proliferate and then differentiate through the hepatocyte lineage, whereas the regenerative response after CCl4 administration is primarily through proliferation of preexisting hepatocytes.

Ribosomal protein L32 of Saccharomyces cerevisiae regulates both splicing and translation of its own transcript.

Ribosomal protein L32 of Saccharomyces cerevisiae regulates the splicing of its own transcript (1, 2) apparently by interacting with a structure composed largely of the 5' exon. However, even in strains overproducing L32 mRNA, e.g. from a cDNA copy of the gene, little accumulation of L32 is observed after a brief pulse label. When the 5' leader of the RPL32 mRNA is replaced by an exogenous leader, the amount of pulse-labeled L32 increases severalfold, suggesting that L32 regulates the translation of its own mRNA, acting through sequences in the 5' region. This conclusion was confirmed by the observation that in cells carrying a chimeric gene in which the L32 leader is fused to LacZ coding sequences, the presence of a second gene that overexpresses L32 itself reduces the level of beta-galactosidase by 50%, in spite of a doubling of L32-lacZ fusion mRNA, presumably due to stabilization of the message. Mutations within the 5' leader that abolish the regulation of splicing also abolish the regulation of translation, suggesting that the regulation of translation by L32 involves a structure similar to that proposed for the regulation of splicing. In cells overproducing L32-mRNA about half the excess mRNA was found in ribonucleoproteins of < 25 S, unassociated with ribosomal particles. Much of the rest was found in ribonucleoproteins of 80-120 S.

Distribution of albumin and alpha-fetoprotein mRNAs in normal, hyperplastic, and preneoplastic rat liver.

The nature of bile duct-like (oval) cells proliferating during chemical hepatocarcinogenesis has been controversial. To investigate this issue further, the authors compared the hepatic distribution of albumin (ALB) and alpha-fetoprotein (AFP) mRNAs in rats in which oval cell proliferation was induced by feeding a choline-devoid diet containing 0.1% ethionine (CDE, a hepatocarcinogenic diet) with that in normal rats and in rats in which biliary epithelial cell hyperplasia was induced by either bile duct ligation or feeding alpha-naphthylisothiocyanate (ANIT). Northern blot analysis in parenchymal and nonparenchymal liver cells isolated from these animals demonstrated that ALB mRNA was present in the hepatocytes of both control and experimental animals, whereas this transcript was detected in nonparenchymal epithelial cells only in CDE-fed rats. Alpha-fetoprotein mRNA was not seen in either parenchymal or nonparenchymal cells isolated from normal or hyperplastic livers induced by bile duct ligation or ANIT feeding. In CDE-fed rats, however, both parenchymal and nonparenchymal cell populations displayed AFP message. In situ hybridization directly demonstrated nonparenchymal cell expression of both ALB and AFP transcripts in CDE-fed rats. Most surprisingly, ALB and AFP mRNAs were also detected by in situ hybridization in occasional nonparenchymal cells located in portal tracts near the limiting plate in normal liver, as well as under conditions associated with bile duct hyperplasia. Immunohistochemical studies of intermediate filament proteins, cytokeratin 19 (a marker of glandular epithelia), vimentin (a marker of mesenchymal lineage), and desmin (a marker of muscle cell differentiation) demonstrated that oval cells, as well as normal and hyperplastic bile duct cells, were positive for cytokeratin 19 and negative for both vimentin and desmin. Cytokeratin-positive oval cells formed duct profiles and were connected to preexisting ductules and ducts. These results are construed to suggest that oval cells proliferating during CDE hepatocarcinogenesis are derived from epithelial cells within the biliary tree. The presence of cells with similar morphologic appearance, periportal location, and AFP and ALB expression in normal liver suggests that these cells may be the progenitors of oval cells induced by some carcinogenic regimens.

The yeast ribosomal protein S7 and its genes.

Ribosomal protein S7 of Saccharomyces cerevisiae is encoded by two genes RPS7A and RPS7B. The sequence of each copy was determined; their coding regions differ in only 14 nucleotides, none of which leads to changes in the amino acid sequence. The predicted protein consists of 261 amino acids, making it the largest protein of the 40 S ribosomal subunit. It is highly basic near the NH2 terminus, as are most ribosomal proteins. Protein S7 is homologous to both human and rat ribosomal protein S4. RPS7A and RPS7B contain introns of 257 and 269 nucleotides, respectively, located 11 nucleotides beyond the initiator AUG. The splicing of the introns is efficient. Either RPS7A or RPS7B will support growth. However, deletion of both genes is lethal. RPS7A maps distal to CDC11 on chromosome X, and RPS7B maps distal to CUP1 on chromosome VIII.

Activated ribosomal RNA synthesis in regenerated rat liver upon inhibition of protein synthesis.

Cycloheximide (Cyh), administered at a dose of 5 mg/kg body wt blocks protein synthesis in normal rat liver (NRL) and regenerating rat liver (RRL). The rate of synthesis of 45S pre-rRNA in RRL, studied after RNA labelling in vivo is activated 2.8 times. Pre-r RNA synthesis in RRL is more sensitive to the stopped translation, but never falls down to the level in NRL. The major contribution to the rDNA transcription activation in RRL comes from the 20-fold increase in the number of pol I molecules engaged in the transcription, the elongation rate being 1.4-fold accelerated. Cyh quenches partially the enhanced rDNA transcription in RRL: the number of pol I molecules and their elongation rate are about 1.7-fold and 1.5-fold higher, respectively, than the corresponding values in NRL after Cyh treatment. The results show that two different mechanisms control the number and the rate of initiation and elongation of RNA polymerase I in rat liver; one of them depends on continuous protein synthesis and can be inactivated by Cyh, the other is Cyh resistant.

The yeast ribosomal protein L32 and its gene.

The yeast ribosomal protein gene RPL32 of Saccharomyces cerevisiae is of particular interest for two reasons: 1) it is adjacent to another ribosomal protein gene, RP29, whose divergent transcription may be driven from the same control sequences, and 2) it appears that the splicing of its transcript is regulated by the product of the gene, ribosomal protein in L32. RPL32 has been analyzed in detail. It is essential for cell growth. Its sequence predicts L32 to be a protein of 105 amino acids, somewhat basic near the NH2 terminus, rather acidic near the COOH terminus, and homologous to ribosomal protein L30 of mammals. The reading frame has been confirmed by partial NH2-terminal analysis of L32. The nucleotide sequence also predicts an intron of 230 nucleotides, which begins with the unusual sequence GTCAGT and ends 40 nucleotides downstream of the consensus sequence TAC-TAAC. The intron has been confirmed by determination of the sequence of a cDNA clone. Transcription initiates 58 nucleotides upstream of the AUG initiation codon, and the polyadenylation site occurs 100 nucleotides downstream of the termination codon. Regulation of the transcription of ribosomal protein genes has been linked to two related consensus sequences. Analysis of the intergenic region between RP29 and RPL32 reveals three copies of these sequences. A deletion removing all three sequences reduces synthesis of a L32-LacZ fusion protein by more than 90%. Some residual activity, however, remains.

Turnover of ribosomal proteins in regenerating rat liver after partial hepatectomy.

The rates of synthesis and degradation of ribosomal proteins, prelabelled with [14C]bicarbonate, were determined as an index of the rate of ribosome turnover in regenerating rat liver. The half-life of ribosomes is about 178 and 75 hr in regenerating and normal liver, respectively. The comparison of turnover rates of ribosomal proteins with the corrected values of rRNA, based on re-utilization of nucleotides, suggests that ribosomes are metabolized as a unit in vivo. There is at least 70% overestimation for ribosome half-life when orotate-labelled RNA is used for turnover determinations. The absolute rate of synthesis is estimated as 3925 and 1081 ribosomes/min per cell in 24 hr regenerating and normal rat liver, respectively.

Autogenous regulation of splicing of the transcript of a yeast ribosomal protein gene.

The gene for a yeast ribosomal protein, RPL32, contains a single intron. The product of this gene appears to participate in feedback control of the splicing of the intron from the transcript. This autogenous regulation of splicing provides a striking analogy to the autogenous regulation of translation of ribosomal proteins in Escherichia coli.