Three target genes for the transcriptional activator Cat8p of Kluyveromyces lactis: acetyl coenzyme A synthetase genes KlACS1 and KlACS2 and lactate permease gene KlJEN1.

The aerobic yeast Kluyveromyces lactis and the predominantly fermentative Saccharomyces cerevisiae share many of the genes encoding the enzymes of carbon and energy metabolism. The physiological features that distinguish the two yeasts appear to result essentially from different organization of regulatory circuits, in particular glucose repression and gluconeogenesis. We have isolated the KlCAT8 gene (a homologue of S. cerevisiae CAT8, encoding a DNA binding protein) as a multicopy suppressor of a fog1 mutation. The Fog1 protein is a homologue of the Snf1 complex components Gal83p, Sip1p, and Sip2p of S. cerevisiae. While CAT8 controls the key enzymes of gluconeogenesis in S. cerevisiae, KlCAT8 of K. lactis does not (I. Georis, J. J. Krijger, K. D. Breunig, and J. Vandenhaute, Mol. Gen. Genet. 264:193-203, 2000). We therefore examined possible targets of KlCat8p. We found that the acetyl coenzyme A synthetase genes, KlACS1 and KlACS2, were specifically regulated by KlCAT8, but very differently from the S. cerevisiae counterparts. KlACS1 was induced by acetate and lactate, while KlACS2 was induced by ethanol, both under the control of KlCAT8. Also, KlJEN1, encoding the lactate-inducible and glucose-repressible lactate permease, was found under a tight control of KlCAT8.

RAG4 gene encodes a glucose sensor in Kluyveromyces lactis.

The rag4 mutant of Kluyveromyces lactis was previously isolated as a fermentation-deficient mutant, in which transcription of the major glucose transporter gene RAG1 was affected. The wild-type RAG4 was cloned by complementation of the rag4 mutation and found to encode a protein homologous to Snf3 and Rgt2 of Saccharomyces cerevisiae. These two proteins are thought to be sensors of low and high concentrations of glucose, respectively. Rag4, like Snf3 and Rgt2, is predicted to have the transmembrane structure of sugar transporter family proteins as well as a long C-terminal cytoplasmic tail possessing a characteristic 25-amino-acid sequence. Rag4 may therefore be expected to have a glucose-sensing function. However, the rag4 mutation was fully complemented by one copy of either SNF3 or RGT2. Since K. lactis appears to have no other genes of the SNF3/RGT2 type, we suggest that Rag4 of K. lactis may have a dual function of signaling high and low concentrations of glucose. In rag4 mutants, glucose repression of several inducible enzymes is abolished.

Regulation of primary carbon metabolism in Kluyveromyces lactis.

In the recent past, through advances in development of genetic tools, the budding yeast Kluyveromyces lactis has become a model system for studies on molecular physiology of so-called "Nonconventional Yeasts." The regulation of primary carbon metabolism in K. lactis differs markedly from Saccharomyces cerevisiae and reflects the dominance of respiration over fermentation typical for the majority of yeasts. The absence of aerobic ethanol formation in this class of yeasts represents a major advantage for the "cell factory" concept and large-scale production of heterologous proteins in K. lactis cells is being applied successfully. First insight into the molecular basis for the different regulatory strategies is beginning to emerge from comparative studies on S. cerevisiae and K. lactis. The absence of glucose repression of respiration, a high capacity of respiratory enzymes and a tight regulation of glucose uptake in K. lactis are key factors determining physiological differences to S. cerevisiae. A striking discrepancy exists between the conservation of regulatory factors and the lack of evidence for their functional significance in K. lactis. On the other hand, structurally conserved factors were identified in K. lactis in a new regulatory context. It seems that different physiological responses result from modified interactions of similar molecular modules.

Cloning and characterization of the lactate-specific inducible gene KlCYB2, encoding the cytochrome b(2) of Kluyveromyces lactis.

In yeast the utilization of lactate requires two enzymes, the D and L-lactate ferricytochrome c oxidoreductase (D and L-LCR), which stereospecifically oxidize D- and L-lactate to pyruvate. These enzymes are nuclearly encoded and localized in mitochondria. In the yeast Kluyveromyces lactis, a mutant devoid of D- and L-LCR activities and unable to grow on racemic lactate was isolated. Transformation of the mutant with a K. lactis genomic library allowed the isolation of the KlCYB2 gene, restoring the growth on lactate and the L-LCR activity. The KlCYB2 gene and its flanking regions were sequenced (Accession No. AJ243324; EMBL/GenBank databases). The deduced amino acid sequence is highly homologous to the corresponding Saccharomyces cerevisiae and Hansenula anomala protein sequences previously characterized. The homology is missed in the N-terminal region, corresponding to the presequence cleaved during import into mitochondria. Analysis of KlCYB2 gene expression indicated that, in contrast to S. cerevisiae, the major regulatory feature is induction by lactate.

Current awareness on yeast.

In order to keep subscribers up-to-date with the latest developments in their field, this current awareness service is provided by John Wiley & Sons and contains newly-published material on yeasts. Each bibliography is divided into 10 sections. 1 Books, Reviews & Symposia; 2 General; 3 Biochemistry; 4 Biotechnology; 5 Cell Biology; 6 Gene Expression; 7 Genetics; 8 Physiology; 9 Medical Mycology; 10 Recombinant DNA Technology. Within each section, articles are listed in alphabetical order with respect to author. If, in the preceding period, no publications are located relevant to any one of these headings, that section will be omitted. (4 weeks journals - search completed 16th Feb 2000)

Isolation and molecular characterization of KlCOX14, a gene of Kluyveromyces lactis encoding a protein necessary for the assembly of the cytochrome oxidase complex.

The yeast Kluyveromyces lactis was mutagenized with ethyl methane sulphonate and mutants unable to grow on respiratory carbon sources were isolated. Functional complementation of one of these mutants led to the isolation of KlCOX14, a gene encoding a 64 amino acid protein which is the functional homologue of Saccharomyces cerevisiae Cox14p, a protein necessary for the assembly of the cytochrome oxidase holoenzyme (Glerum et al., 1995). The disruption of KlCOX14 resulted in the absence of the absorption bands relative to cytochromes a and a(3) and in the complete loss of respiratory activity. Klcox14 mutants display the typical phenotype of pet mutants and have a reduced growth rate. In addition, unlike the wild-type, Klcox14 mutants are able to grow by fermentation also in the presence of low glucose. The nucleotide sequence of KlCOX14 has been deposited in the EMBL databank with Accession No. AJ238801.

Transcriptional regulation of the KlDLD gene, encoding the mitochondrial enzyme D-lactate ferricytochrome c oxidoreductase in Kluyveromyces lactis: effect of Klhap2 and fog mutations.

Expression of the Kluyveromyces lactis KlDLD gene, encoding the mitochondrial enzyme D-lactate ferricytochrome c oxidoreductase (D-LCR), is subject to two metabolic controls at the transcriptional level: induction by lactate, the substrate of the D-LCR enzyme, and repression by glucose. By Northern analysis we determined the kinetics of the two regulatory processes and, by measurement of the expression of LacZ gene fused to the KlDLD promoter, we identified cis-elements involved in glucose repression and lactate induction. The effect of trans-acting factors on the transcription of KlDLD has been analyzed. The KlDLD gene is controlled by the products of the FOG1 and FOG2 genes, previously identified as involved in glucose de-repression. Moreover, the KlDLD gene is regulated by the product of KlHAP2, homologous to the HAP2 gene which in Saccharomyces cerevisiae is required for the induction of genes encoding mitochondrial components, upon shifting from a fermentable to a non-fermentable carbon source. We have demonstated that the KlHAP2 gene is necessary both for the lactate induction of KlDLD mRNA synthesis and for growth on this oxidative carbon source.

Influence of mutations in hexose-transporter genes on glucose repression in Kluyveromyces lactis.

The variability of Kluyveromyces lactis strains in sensitivity to glucose is correlated with genetic differences in Kluyveromyces hexose transporter (KHT) genes. The glucose sensitive strain JA6 was shown to contain an additional gene, KHT2, not found in strains that are less sensitive. KHT2 is tandemly arranged with KHT1 which is identical to the low-affinity transporter gene RAG1, except for the C-terminus. Sequence analysis indicated that most of KHT2 had been lost by a recombination event between KHT1 and KHT2 generating the chimeric gene RAG1. Recombination between KHT1 and KHT2 was also found in mutants of JA6 selected as 2-deoxyglucose resistant colonies. These mutants, like kht1 kht2 double mutants were unable to grow on glucose when respiration was blocked (Rag- phenotype) and glucose repression was strongly reduced. kht1 or kht2 single mutants of JA6 were Rag+ but still an influence of the kht mutations on glucose repression was detectable. Repression was not affected in a Rag- mutant deleted for the phosphoglucose isomerase gene suggesting that the influence of transporter genes on repression is not caused by a reduction of the glycolytic flux. The data rather suggest that sensitivity to glucose repression is dependent on the rate of glucose uptake.

FOG1 and FOG2 genes, required for the transcriptional activation of glucose-repressible genes of Kluyveromyces lactis, are homologous to GAL83 and SNF1 of saccharomyces cerevisiae.

The fog1 and fog2 mutants of the yeast Kluyveromyces lactis were identified by inability to grow on a number of both fermentable and non-fermentable carbon sources. Genetic and physiological evidences suggest a role for FOG1 and FOG2 in the regulation of glucose-repressible gene expression in response to a glucose limitation. The regulatory effect appears to be at the transcriptional level, at least for beta-galactosidase. Both genes have been cloned by complementation and sequenced. FOG1 is a unique gene homologous to GAL83, SIP1 and SIP2, a family of regulatory genes affecting glucose repression of the GAL system in Saccharomyces cerevisiae. However, major differences exist between fog1 and gal83 mutants. FOG2 is structurally and functionally homologous to SNF1 of S. cerevisiae and shares with SNF1 a role also in sporulation.

IMP2, a gene involved in the expression of glucose-repressible genes in Saccharomyces cerevisiae.

Two mutants carrying different deletions of the IMP2 coding sequence of Saccharomyces cerevisiae, delta T1, which encodes a protein lacking the last 26 C-terminal amino acids, and delta T2, which completely lacks the coding region, were analysed for derepression of glucose-repressible maltose, galactose, raffinose and ethanol utilization pathways in response to glucose limitation. The role of the IMP2 gene product in the regulation of carbon catabolite repressible enzymes maltase, invertase, alcohol dehydrogenase, NAD-dependent glutamate dehydrogenase (NAD-GDH) and L-lactate:ferricytochrome-c oxidoreductase (L-LCR) was also analysed. The IMP2 gene product is required for the rapid glucose derepression of all above-mentioned carbon source utilization pathways and of all the enzymes except for L-LCR. NAD-GDH is regulated by IMP2 in the opposite way and, in fact, this enzyme was released at higher levels in both imp2 mutants than in the wild-type strain. Therefore, the product of IMP2 appears to be involved in positive and negative regulation. Both deletions result in growth and catalytic defects; in some cases partial modification of the gene product yielded more dramatic effects than its complete absence. Moreover, evidence is provided that the IMP2 gene product regulates galactose- and maltose-inducible genes at the transcriptional level and is a positive regulator of maltase, maltose permease and galactose permease gene expression.

A kluyveromyces lactis gene homologue to AAC2 complements the Saccaromyces cerevisiae op1 mutation.

A mutation (op1) in the Saccharomyces cerevisiae AAC2 gene, which codes for the most abundant ADP/ATP carrier isoform, results in lack of mitochondrial-dependent growth and in an as yet unexplained petite-negative phenotype. A gene from the petite-negative yeast Kluyveromyces lactis has been isolated by complementing in multicopy the op1 mutation of S. cerevisiae. This gene, designated KIAAC, can complement the petite-negative phenotype of op1 as well as its inability to grow on nonfermentable carbon sources. KIAAC contains a 915-base pair open reading frame coding for a protein of 305 amino acids which shows a high degree of identity to AAC2. The K. lactis ADP/ATP carrier also shares identity with other known ADP/ATP carrier sequences. In particular, the degree of identity of KIAAC is higher with the Neurospora crassa carrier (80.1%) than with AAC1 (76.6%). The nucleotide sequence upstream of the KIAAC coding region was found to contain a long DNA segment with no coding potential, but presenting features of highly regulated promoter sequences.

Carbon catabolite repression in Kluyveromyces lactis: isolation and characterization of the KIDLD gene encoding the mitochondrial enzyme D-lactate ferricytochrome c oxidoreductase.

In the "petite-negative" yeast Kluyveromyces lactis carbon catabolite repression of some cytoplasmic enzymes has been observed. However, with respect to mitochondrial enzymes, in K. lactis, unlike the case in the "petite-positive" yeast Saccharomyces cerevisiae, growth on fermentable carbon sources does not cause repression of respiratory enzymes. In this paper data are reported on carbon catabolite repression of mitochondrial enzymes in K. lactis, in particular on L- and D-lactate ferricytochrome c oxidoreductase (LCR). The L- and D-LCR (E.C. 1123, E.C. 1124) in yeast catalyze the stereospecific oxidation of D and L isomers of lactate to pyruvate. This pathway is linked to the respiratory chain, cytochrome c being the electron acceptor of the redox reaction. We demonstrate that the level of mitochondrial D- and L-LCR is controlled by the carbon source, being induced by the substrate lactate and catabolite-repressed by glucose. We cloned the structural gene for D-LCR of K. lactis (KlDLD), by complementation of growth on D,L-lactate in the S. cerevisiae strain WWF18-3D, carrying both a CYB2 disruption and the dld mutation. From the sequence analysis an open reading frame was identified that could encode a polypeptide of 579 amino acids, corresponding to a calculated molecular weight of 63,484 Da. Analysis of mRNA expression indicated that glucose repression and induction by lactate are exerted at the transcriptional level.

Glucose transport in the yeast Kluyveromyces lactis. I. Properties of an inducible low-affinity glucose transporter gene.

In most strains of Kluyveromyces lactis, respiratory function is not required for growth on glucose. However, some natural variant strains are unable to grow when respiration is blocked by specific inhibitors (Rag- phenotype). This phenotype is due to an allelic variation of the chromosomal gene RAG1. The sensitive variants have a recessive allele rag1. The RAG1 gene has been cloned by complementation of a rag1 strain from a genomic bank derived from a Rag+ strain. The nucleotide sequence of the cloned gene indicated that the RAG1 product was a sugar transporter protein. The amino acid sequence deduced from the gene structure contained the 12 hydrophobic segments typical of a transmembrane protein, and showed a high degree of homology with the GAL2 (galactose permease) and HXT2 (a high-affinity glucose transporter) proteins of Saccharomyces cerevisiae. In a rag1 null mutant, as in the natural rag1 variant, uptake of glucose at high external glucose concentrations was impaired. The RAG1 protein appears to correspond to a low-affinity glucose transporter. Transcription of the RAG1 gene, which was undetectable when cells were grown in glycerol, was induced by glucose. It is concluded that respiration-dependent growth on glucose of the Rag- variant strains is due to a defect in this inducible glucose transport system.

A phosphoglucose isomerase gene is involved in the Rag phenotype of the yeast Kluyveromyces lactis.

The rag2 mutant of Kluyveromyces lactis cannot grow on glucose when mitochondrial functions are blocked by various mitochondrial inhibitors, suggesting the presence of a defect in the fermentation pathway. The RAG2 gene has been cloned from a K. lactis genomic library by complementation of the rag2 mutation. The amino acid sequence of the RAG2 protein deduced from the nucleotide sequence of the cloned RAG2 gene shows homology to the sequences of known phosphoglucose isomerases (PGI and PHI). In vivo complementation of the pgi1 mutation in Saccharomyces cerevisiae by the cloned RAG2 gene, together with measurements of specific PGI activities and the detection of PGI proteins, confirm that the RAG2 gene of K. lactis codes for the phosphoglucose isomerase enzyme. Complete loss of PGI activity observed when the coding sequence of RAG2 was disrupted leads us to conclude that RAG2 is the only gene that codes for phosphoglucose isomerase in K. lactis. The RAG2 gene of K. lactis is expressed constitutively, independently of the growth substrates (glycolytic or gluconeogenic). Unlike the pgi1 mutants of S. cerevisiae, the K. lactis rag2 mutants can still grow on glucose, however they do not produce ethanol.

Isolation and characterization of carbon catabolite repression mutants in Saccharomyces cerevisiae.

Two carbon catabolite repression mutants of S. cerevisiae were isolated and characterized. In spite of the selection procedure (red colonies after tetrazolium overlay at high glucose concentration) the mutants exhibited a respiration which was as repressed as that of the parental strain or even more repressed. When grown at high glucose concentration the mutants display hyper-repression of cytochrome aa3 and of certain mitochondrial enzymes (L- and D-lactate dehydrogenases) but not of others (malate dehydrogenase, succinate dehydrogenase), indicating the existence of separate control sites for the different genes involved in the mitochondrial biogenesis. The data obtained pointed out that the same mutation affects both repression and derepression. In addition, the mutation(s) give rise to the complete derepression of the cytoplasmic enzyme NAD-glutamate dehydrogenase at 10% glucose whereas the enzyme is normally repressed at 3% glucose. The results of the genetic analysis indicate the mitochondrial nature of the mutation(s).

RAG1 and RAG2: nuclear genes involved in the dependence/independence on mitochondrial respiratory function for growth on sugars.

The analysis of five independent isolates of Kluyveromyces lactis shows that CBS 2359, CBS 683 and CBS 4574 could grow in the presence of mitochondrial inhibitors (antimycin A, oligomycin or erythromycin) and that CBS 2360 and CBS 141 were unable to grow in the presence of drugs. The resistant growth was observed only on glucose and not on other fermentable carbon sources (galactose, lactose). The phenotype 'growth on glucose in the presence of mitochondrial inhibitors' was called Rag+. This phenotype was found to be controlled by two unlinked nuclear genes: RAG1 and RAG2. Either of their recessive alleles, rag1 and rag2, led to the Rag- phenotype (i.e. the failure of growth on glucose in the presence of antimitochondrial drugs). Rag- strains represent the case in which fermentative growth becomes absolutely dependent on the functioning of the normal respiratory chain.

Total thyroidectomy for benign thyroid disease: when and why.

Surgical complications after total thyroidectomy (TT) and subtotal thyroidectomy (STT) are analysed in a series of 364 patients operated on over a 36-month period. All operations were carried out because of the following 3 groups of disease: malignant tumors, multinodular goiter and Graves' disease. The difference among the incidence of surgical complications resulted to be not statistically significant when as discriminating factors the type of surgery or disease were used, while the difference was statistically significant when the results obtained in the 2 groups of patients operated only once or undergoing reoperative surgery for recurrence, were compared. Based on these observations, the surgical approach consistent with the above mentioned types of thyroid disease is reported, and the preference for total thyroidectomy is justified to a larger extent by what has been done to-date also in case of benign thyroid disease. The choice of the type of surgery should always be made, based on a careful clinical and intraoperative assessment of each case.

Pathophysiology and predictivity of postoperative hypothyroidism.

In a series of 107 patients operated on for hyperthyroidism, the incidence of postoperative hypothyroidism has been evaluated, stressing its major causes. These appear related to a decreased function of residual parenchyma, autoimmune diseases, previous irradiation of the neck, preexisting defects of the hormonogenesis. The importance of the thyroid remnant has been enphasized together with the preservation of its blood supply. A higher incidence of hypothyroidism has been observed after more extensive operations, particularly subtotal thyroidectomy, in patients affected by Graves' disease. Finally, the need for short and long term follow-up after surgery is outlined and whether a replacement therapy is required or not. It is concluded that, postoperative hypothyroidism should not be considered a complication but a predictable consequence.