Biological effects of targeted inactivation of hepatocyte growth factor-like protein in mice.

Hepatocyte growth factor-like protein (HGFL) is a liver-derived serum glycoprotein involved in cell proliferation and differentiation, and is proposed to have a fundamental role in embryogenesis, fertility, hematopoiesis, macrophage activation, and tissue repair. To assess the in vivo effects of total loss of HGFL, we generated mice with targeted disruption of the gene resulting in loss of the protein. Disruption of the HGFL gene allowed for normal embryogenesis, and followed a Mendelian pattern of genetic transmission. Mice homozygous for the targeted allele (HGFL-/- mice) are fertile, and grow to adulthood without obvious phenotypic abnormalities in unchallenged animals, except for development of lipid-containing cytoplasmic vacuoles in hepatocytes throughout the liver lobules. These histologic changes are not accompanied by discernible changes in synthetic or excretory hepatic functions. Hematopoiesis appears unaltered, and although macrophage activation is delayed in the absence of HGFL, migration to the peritoneal cavity upon challenge with thioglycollate was similar in HGFL-/- and wild-type mice. Challenged with incision to skin, HGFL-/- mice display normal wound healing. These data demonstrate that HGFL is not essential for embryogenesis, fertility, or wound healing. HGFL-deficient mice will provide a valuable means to assess the role of HGFL in hepatic and systemic responses to inflammatory and infectious stimuli in vivo.

Expansion of transplanted hepatocytes during liver regeneration.

BACKGROUND: Successful clinical application of hepatocyte transplantation has been limited by poor engraftment of the recipient liver by transplanted hepatocytes. METHODS: To address the hypothesis that liver regeneration induced by an acute hepatotoxic injury promotes expansion of transplanted hepatocytes, we injected beta-galactosidase-labeled hepatocytes intrasplenically into mice 24 hr after treatment with carbon tetrachloride (CCl4) and into untreated controls. RESULTS: Macroscopic examination of whole liver segments identified clusters of transplanted hepatocytes uniformly spread on the capsular surface of the recipient liver and in the liver core following the distribution pattern of portal vein branches. Frozen sections showed that although the degree of initial engraftment of transplanted hepatocytes was similar in CCl4-treated and control livers, there was a fourfold increase of engrafted hepatocytes in CCl4-treated livers 10 days after transplantation which persisted to 28 days. CONCLUSIONS: We conclude that the number of transplanted hepatocytes increases in response to regeneration signal triggered by an acute hepatocyte-specific liver injury.

Survival and induction of SOS in Escherichia coli treated with cisplatin, UV-irradiation, or mitomycin C are dependent on the function of the RecBC and RecFOR pathways of homologous recombination.

Resistance of tumors to drugs such as cisplatin and mitomycin C (MMC) is an important factor limiting their usefulness in cancer chemotherapy. The antitumor effects of these drugs are due to the formation of bifunctional adducts in DNA, with cisplatin causing predominantly intrastrand-crosslinks and MMC causing interstrand-crosslinks. The SOS chromotest was used to study the cellular mechanisms that process DNA damage in Escherichia coli exposed to cisplatin, ultraviolet irradiation (UV) and MMC and subsequently facilitate the production of a molecular signal for induction of the SOS response. Strains used in the SOS chromotest have a fusion of lacZ with the sfiA (sulA) gene so that the amount of SOS inducing signal, which is modulated by the ability of the cell to repair DNA, is measured by assaying beta-galactosidase activity. SOS induction in a strain proficient in homologous recombination (HR) was compared with that in isogenic strains deficient in HR due to a blocked RecBC pathway caused by a recB mutation or a blocked RecFOR pathway caused by a recO mutation. The effect of cisplatin treatment in a uvrA mutant strain blocked at the first step of NER was compared with that in an isogenic strain proficient in NER. Cellular resistance was measured as percent colony forming units (cfu) for cells treated with increasing doses of cisplatin, MMC and UV relative to that in untreated control cultures. The importance of both HR pathways for resistance to these treatments was demonstrated by decreased survival in mutants with the recB mutant being more sensitive than the recO mutant. SOS induction levels were elevated in the sensitive recB strain relative to the HR proficient strain possibly due to stalled and/or distorted replication forks at crosslinks in DNA. In contrast, induction of SOS was dependent on RecFOR activity that is thought to act at daughter strand gaps in newly synthesized DNA to mediate production of the signal for SOS induction. Proficiency in NER was necessary for both survival and high levels of SOS induction in cisplatin treated cells.

Zonal regulation of gene expression during liver regeneration of urokinase transgenic mice.

Liver gene transcription plays a fundamental role in the hepatic reparative response to injury. However, little is known about the functional relationship of gene expression between diseased and regenerative compartments following a liver injury. To address the hypothesis that the control of gene expression and the cellular proliferative response are specific to diseased and regenerative liver compartments independently, we assessed the expression of liver growth modulators, hepatocyte proliferation, and apoptosis in transgenic livers overexpressing the urokinase-type plasminogen activator (uPA). uPA livers have regenerative nodules that are visually distinct from the surrounding diseased compartments. Northern analyses using RNA from microdissected regenerative and diseased compartments showed that, among the known liver growth factors studied, there was a selective increase in the expression of hepatocyte growth factor (HGF) in diseased compartments above the levels seen in regenerative compartments and in livers of nontransgenic littermates. Despite the high level of HGF mRNA in diseased compartments, hepatocyte proliferation was low. In contrast, in regenerative compartments, where HGF mRNA was low, hepatocyte proliferation was abundant. For growth inhibitors, mRNA expression for transforming growth factor beta1 (TGF-beta1), p53, and activin A was increased in diseased compartments, where hepatocytes displayed apoptosis. These findings define a zone-specific regulation of gene expression in injured livers and point to an important role of the diseased microenvironment in the fate of hepatocytes during the regenerative process.