[Implications of nutritional status for onset and characteristics of experimental acute pancreatitis in a mouse model]. / Auswirkungen des Ernährungszustands auf die Ausprägung einer experimentellen akuten Pankreatitis der Maus.

BACKGROUND: Due to uncontrolled activation of digestive enzymes produced within the pancreas, acute pancreatitis is a disease with a great potential for complications and variable course. Since the pathophysiological steps of human pancreatitis can only be inadequately investigated, various animal models were established to study the course of disease. The model of supramaximal caerulein stimulation allows to gain insights into intracellular events of the early phase of acute pancreatitis. Usually, overnight fasted animals are used for the model of acute pancreatitis to achieve a maximum zymogen granula accumulation and a standardised initial situation due to diminished secretion of CCK. Furthermore, the role of the nutritional state for pathogenesis and course of acute pancreatitis is controversially discussed. The aim of the study was to investigate the impact of the nutritional status on pancreatic injury in experimental acute pancreatitis. METHODS: Using standardised supramaximal caerulein stimulation (dose: 50 µg/kg; time intervals, 1/h; max. 7×), acute oedematous interstitial pancreatitis in fasted and non-fasted mice was induced. Pancreatic injury was locally characterised by pancreatic oedema, histopathological alterations and the release of pancreatic enzyme to the serum while systemic alterations were objectified by IL-6, CRP und pulmonal MPO. RESULTS: 1) Increased pancreatic serum enzyme levels after induction of acute pancreatitis in non-fasted animals do not reflect a greater affection of the pancreas since amylase and lipase in serum and pancreatic tissue correlate proportionally. The induction of acute pancreatitis provoked release of 1.3 % and 0.7 % of amylase and lipase, respectively, independently of nutritional status. 2) Neither local nor systemic parameters of pancreatic injury were significantly altered by the nutritional regimen. Pathohistologic investigations revealed increase of zymogen granula portion and cell size in non-fasted mice but no further differences compared with fasted animals. 3) During a 16-hour recovery period (no further caerulein injection), local and systemic parameters normalised. DISCUSSION: In the relatively mild model of pancreatitis induced by hormonal hyperstimulation, there was no greater pancreatic injury despite higher intrapancreatic enzyme accumulation in non-fasted animals indicating a steady state between potentially damaging and protective factors and mechanisms.

Mitochondrial DNA deletions sensitize cells to apoptosis at low heteroplasmy levels.

A heterogeneous group of multisystem disorders affecting various tissues and often including neuromuscular symptoms is caused by mutations of the mitochondrial genome, which codes 13 polypeptides of oxidative phosphorylation (OXPHOS) complexes and 22 tRNA genes needed for their translation. Since the link between OXPHOS dysfunction and clinical phenotype remains enigmatic in many diseases, a possible role of enhanced apoptosis is discussed besides bioenergetic crisis of affected cells. We analyzed the proapoptotic impact of the mitochondrial 5kb common deletion (CD), affecting five tRNA genes, in transmitochondrial cybrid cell lines and found a slightly enhanced sensitivity to exogenous oxidative stress (H2O2) and a pronounced sensitization against death receptor stimulation (TRAIL) at a rather low CD heteroplasmy level of 22%. Mitochondrial deletions confer enhanced susceptibility against proapoptotic signals to proliferating cells, which might explain the elimination of deletions from hematopoietic stem cells.

The constitutive AHSB4 promoter--a novel component of the Arxula adeninivorans-based expression platform.

An Arxula adeninivorans-AHSB4 gene, encoding histone H4, was isolated and characterized. The gene includes a coding sequence of 363 bp disrupted by a 51-bp intron, similar to the situation in other fungal H4 genes. The identity of the gene was confirmed by the high degree of homology of the derived amino acid sequence with that of other H4 histones. The gene is strongly and constitutively expressed, maintaining this expression profile under salt-stress conditions. The AHSB4 promoter was tested for suitability in heterologous gene expression using genes encoding the intracellular green fluorescent protein and the secreted human serum albumin (HSA) for assessment. Plasmids incorporating respective expression cassettes were used to transform the host strain A. adeninivorans LS3, which forms budding cells at 30 degrees C, and strain 135, which forms mycelia under these conditions. Transformants of both types were found to harbor a single copy of the heterologous DNA. Strong constitutive expression was observed during culture in salt-containing and salt-free media, as expected from the expression profile of AHSB4. In 200-ml shake-flask cultures, maximal HSA levels of 20 mg l(-1) culture medium were achieved. This productivity could be increased to 50 mg l(-1 )in strains harboring two copies of the expression cassette. The AHSB4 promoter thus provides an attractive component for constitutive heterologous gene expression under salt-free and salt-stress conditions.

Regulation of the AEFG1 gene, a mitochondrial elongation factor G from the dimorphic yeast Arxula adeninivorans LS3.

Oxygen influences the synthesis of mitochondrial proteins by alteration of the expression of mitochondrial genes and several nuclear genes. One of the genes localised in the nucleus is the EFG1 gene that encodes the mitochondrial elongation factor G (MEF-G). This unique gene (AEFG1) has been isolated from the non-conventional dimorphic yeast, Arxula adeninivorans LS3. The AEFG1 gene comprises a ORF of 2,274 bp, which corresponds to 757 amino acids. In the present study, the regulation of AEFG1 has been analysed for different morphological stages of A. adeninivorans and various culture conditions. It was demonstrated that the transfer of aerobically growing cultures to anaerobic conditions resulted in an accumulation of AEFG1 transcript, correlating with an increase in AMEF-G protein concentration. Since this regulation occurred in budding-cell culture growing at 30 degrees C and in both of the mycelial cultures grown at 45 degrees C and 30 degrees C, respectively, it was the oxygen level (but not the cultivation temperature or the morphological stage) which influenced the AEFG1 regulation.

Genetic transformation and biotechnological application of the yeast Arxula adeninivorans.

The relatively unknown, non-pathogenic, dimorphic, haploid, ascomycetous yeast Arxula adeninivorans exhibits some unusual properties which are of biotechnological interest. The yeast is able to assimilate and ferment many compounds as sole source of carbon and/or nitrogen, it utilises n-alkanes and degrades starch efficiently. A. adeninivorans features such as thermo- and haloresistance as well as the yeast's uncommon growth and secretion behaviour should be especially emphasised. In media containing up to 20% NaCl, A. adeninivorans is able to grow at cultivation temperatures up to 48 degrees C. Additionally, the dimorphism of the yeast is unusual. Arxula grows at up temperatures of up to 42 degrees C as budding cells, which turn into mycelia at higher temperatures. This environmentally conditioned dimorphism is reversible and budding is reestablished when the cultivation temperature is decreased below 42 degrees C. Alteration of morphology correlates with changes in secretion behaviour. Mycelium cultures accumulate two-fold higher protein concentrations and contain two- to five-fold higher glucoamylase and invertase activities in the medium than budding cells. Based on these unusual properties, Arxula adeninivorans is used for heterologous gene expression and as a gene donor to construct more suitable yeasts for biotechnology. For example the Arxula glucoamylase gene was successfully expressed in Saccharomyces cerevisiae and Kluyveromyces lactis. Both transformed yeasts are able to assimilate and ferment starch as carbon source. A transformation system is used for heterologous gene expression which is based on integration of linearised DNA fragments in two to ten copies, e.g. into the 25S rDNA of A. adeninivorans by homologous recombination. The obtained transformants are mitotically stable. The expression of the lacZ gene from E. coli as well as the XylE gene from Pseudomonas putida indicates the suitability of A. adeninivorans as host for heterologous gene expression.

Halotolerance of the yeast Arxula adeninivorans LS3.

The non-pathogenic, dimorphic, ascomycetous yeast Arxula adeninivorans LS3 is halotolerant. It can grow in a minimal medium containing up to 20% NaCl. The growth parameters are only weakly influenced by 10% NaCl. However, NaCl in a concentration higher than 10% causes a decrease in the specific growth rate, a longer adaptation phase and a lower cell count in the stationary growth phase. Concentrations of glycerol and trehalose, which differed 100-fold in magnitude in a salt free medium, are also influenced differently by salt. NaCl induces accumulation of intracellular glycerol in exponentially growing cells but a reduced concentration of intracellular trehalose in stationary cells. Transcripts of the genes ARFC3, encoding a component of the replication factor C, and GAA, encoding a secretory glucoamylase, can be detected only in cells cultured in media with NaCl concentrations below 10%. Furthermore, NaCl in high concentration reduces the level of secreted proteins including glucoamylase end invertase.

Morphology-related effects on gene expression and protein accumulation of the yeast Arxula adeninivorans LS3.

The dimorphism of the yeast Arxula adeninivorans LS3 is regulated by cultivation temperatures. Up to 42 degrees C the yeast grows as budding cells, which turn to mycelia at higher temperatures. To test whether the dimorphism is exclusively induced by high temperatures or also by other conditions, mutants were selected with an altered behaviour with respect to dimorphism. After mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine, five of 25,000 colonies formed a very rough surface consisting of mycelia at 30 degrees C, in contrast to the wild-type. These mutants allow temperature-mediated and morphology-related effects on gene expression and protein accumulation to be distinguished. Budding cells and mycelia showed different expression of genes encoding secretory proteins at the same temperature. Mycelia secreted two-fold more protein than budding cells, including the enzymes glucoamylase and invertase. This indicated that morphology, rather than temperature, is the decisive factor in the analysed processes.

AILV1 gene from the yeast Arxula adeninivorans LS3--a new selective transformation marker.

The ILV1 gene of the yeast Arxula adeninivorans LS3 (AILV1) has been cloned from a genomic library, characterized and used as an auxotrophic selection marker for transformation of plasmids into this yeast. One copy of the gene is present in the Arxula genome, comprising 1653 bp and encoding 550 amino acids of the threonine deaminase. The protein sequence is similar (60.55%) to that of the threonine deaminase from Saccharomyces cerevisiae encoded by the gene ILV1. The protein is enzymatically active during the whole period of cultivation, up to 70 h. Maximal activities, as well as protein concentrations of this enzyme, were achieved after cultivation times of 20-36 h. The AILV1 gene is a suitable auxotrophic selection marker in transformation experiments using an Arxula adeninivorans ilv1 mutant and a plasmid containing this gene, which is fused into the 25S rDNA of Arxula adeninivorans. One to three copies of the linearized plasmid were integrated into the 25S rDNA by homologous recombination. Transformants resulting from complementation of the ilv1 mutation can be easily and reproducibly selected and in addition are mitotically stable. Therefore, the described system is preferred to the conventional selection for hygromycin B resistance.

Temperature-dependent dimorphism of the yeast Arxula adeninivorans Ls3.

Arxula adeninivorans Ls3 is described as an ascomycetous, arthroconidial, anamorphic, xerotolerant yeast, which was selected from wood hydrolysates in Siberia. By using minimal salt medium or yeast-extract-peptone-medium with glucose or maltose as carbon source it was shown that this yeast is able to grow at up to 48 degrees C. Increasing temperatures induce changes in morphology from the yeast phase to mycelia depending on an altered programme of gene expression. This dimorphism is an environmentally conditioned (reversible) event and the mycelia can be induced at a cultivation temperature of 45 degrees C. Depending on the morphology of strain Ls3 (yeast phase or mycelia) the secretion behaviour as well as the spectrum of polypeptides accumulated in the culture medium changed. The activities of the accumulated extracellular enzymes glucoamylase and invertase were 2 to 3 times higher in cultures grown at 45 degrees C than in those grown at 30 degrees C. While the level of the glucoamylase protein secreted from mycelia between 45 and 70 hours did not change, biochemical activity decreased after a cultivation time of 43 hours. It was shown that this effect depended on both the catabolic repression of the glucoamylase by glucose and the thermal inactivation of this enzyme in media without or with low concentrations of starch or maltose.

Comparative biochemical, genetical and immunological studies of glucoamylase producing Arxula adeninivorans yeast strains.

Seven Arxula adeninivorans strains originating from The Netherlands (CSIR 1136, CSIR 1138 and CBS 8244T), South Africa (CSIR 1147, CSIR 1148 and CSIR 1149) and Siberia (Ls3) were compared concerning their secretory glucoamylase. Within the spectrum of secretory polypeptides obtained by SDS-polyacrylamide gel electrophoresis, the glucoamylase corresponding polypeptide, could be identified by means of specific antibodies directed against the glucoamylase of strain Ls3. The molecular masses of the glucoamylases vary from 84 to 95 kDa. After endoglycosidase F treatment of the secretory proteins, the N-linked carbohydrate content for each glucoamylase could be quantified at about 25%. Glucoamylase activity staining of secretory proteins separated under nondenaturing conditions revealed one glucoamylase active protein for the Dutch strains and two active forms for the strains originating from South Africa and Siberia. Highest activities of glucoamylase can be measured at the end of the exponential growth phase for each strain. The Dutch strain CSIR 1138 secretes the highest activity. Optimum values for temperature and pH were determined and compared. By means of pulsed field gel electrophoresis and Southern analysis, the glucoamylase corresponding gene could be localized on the second of the four chromosomes of each yeast strain.