Metabolism of biotin and analogues of biotin by microorganisms. IV. Degradation of biotin, oxybiotin, and desthiobiotin by Lactobacillus casei

Birnbaum, Jerome (University of Cincinnati, Cincinnati, Ohio), and Herman C. Lichstein. Metabolism of biotin and analogues of biotin by microorganisms. IV. Degradation of biotin, oxybiotin, and desthiobiotin by Lactobacillus casei. J. Bacteriol. 92:925-930. 1966.-Lactobacillus casei degrades biotin when it is present in excess to products not utilizable for growth by L. plantarum or Saccharomyces cerevisiae. Degrading activity was initiated in the early stationary phase and was controlled by the pH of the medium. Nonproliferating cells, grown previously in excess biotin for 40 hr, metabolized oxybiotin and desthiobiotin as well as biotin. Cells grown in low biotin, or in excess biotin for 20 hr, did not degrade either analogue. Oxybiotin was 50% as active as biotin for growth, whereas desthiobiotin acted as a competitive inhibitor. Cells grown in excess biotin for 40 hr, but not 20 hr, overcame the inhibitory effect of desthiobiotin, when subcultured to media containing a normally inhibitory concentration of the analogue. Moreover, the level of desthiobiotin dropped rapidly during the first 4 to 6 hr before growth ensued. The data indicate that growth in excess biotin enables L. casei to degrade desthiobiotin and, thereby, to overcome the inhibitory effect of the analogue.     

The biotin requirement of HeLa cells

We have examined the effect of alterations in the biotin content of the medium on the growth, viability, biotin content, and the activities of biotin-dependent and biotin-independent enzymes of the HeLa cells. The inclusion in the growth medium of avidin, which almost irreversibly binds with biotin (K_d, 10^?15 M), results in an increase in cellular biotin content and biotin enzyme activity over that seen when the cells are grown in a biotin-depleted medium. The addition of avidin-bound biotin to the growth medium led to a forty-fold increase in cellular biotin when compared to the inclusion of an equivalent amount of free biotin in the medium. HeLa cells are able to internalize avidin-bound biotin. Biotin is released from this complex to function as the prosthetic group of biotin enzymes. HeLa cells do have a nutritional requirement for biotin.     

Action of 5-(2-thienyl) valeric acid as a biotin antagonist

5-(2-Thienyl)valeric acid (TVA), a biotin analogue which can be easily prepared through chemical process, inhibited the growth of a biotin synthesizing Rhodotorula glutinis. The growth inhibition was reversed by the addition of biotin. Among biotin intermediates, dethiobiotin and 7,8-diaminopelargonic acid reversed the inhibition by TVA, while 7-keto-8-amino-pelargonic acid and pimelic acid did not. From these results, it was concluded that TVA is a biotin antagonist which probably acts as an inhibitor of biotin biosynthesis.     

The biotin requirement of human fibroblasts in culture

We have examined the effect of biotin deficiency on the growth, viability, biotin content, and the activities of biotin-dependent and biotin-independent enzymes of human fibroblasts. There was a significant decrease in viability of the biotin-deficient cells even when the medium contained serum lipids. Propionyl CoA carboxylase activity reflected the decreased biotin content of the cells whereas alkaline phosphatase activity was not altered. The inclusion of avidin bound biotin in the growth medium resulted in an increase in biotin content as well as propionyl CoA carboxylase activity over that seen when free biotin was included in the medium. The cells appeared to bind and internalize the avidin-biotin complex by adsorptive pinocytosis. These findings are similar to those demonstrated using HeLa cells.     

Peroxisomes are involved in biotin biosynthesis in Aspergillus and Arabidopsis

Among the eukaryotes only plants and a number of fungi are able to synthesize biotin. Although initial events leading to the biosynthesis of biotin remain largely unknown, the final steps are known to occur in the mitochondria. Here we deleted the Aopex5 and Aopex7 genes encoding the receptors for peroxisomal targeting signals PTS1 and PTS2, respectively, in the filamentous fungus Aspergillus oryzae. In addition to exhibiting defects in the peroxisomal targeting of either PTS1 or PTS2 proteins, the deletion strains also displayed growth defects on minimal medium containing oleic acid as the sole carbon source. Unexpectedly, these peroxisomal transport-deficient strains also exhibited growth defects on minimal medium containing glucose as the sole carbon source that were remediated by the addition of biotin and its precursors, including 7-keto-8-aminopelargonic acid (KAPA). Genome database searches in fungi and plants revealed that BioF protein/KAPA synthase, one of the biotin biosynthetic enzymes, has a PTS1 sequence at the C terminus. Fungal ΔbioF strains expressing the fungal and plant BioF proteins lacking PTS1 still exhibited growth defects in the absence of biotin, indicating that peroxisomal targeting of KAPA synthase is crucial for the biotin biosynthesis. Furthermore, in the plant Arabidopsis thaliana, AtBioF localized to the peroxisomes through recognition of its PTS1 sequence, suggesting involvement of peroxisomes in biotin biosynthesis in plants. Taken together we demonstrate a novel role for peroxisomes in biotin biosynthesis and suggest the presence of as yet unidentified peroxisomal proteins that function in the earlier steps of biotin biosynthesis.     

Biotin biosynthesis in Mycobacterium tuberculosis: physiology,biochemistry and molecular intervention

Biotin is an important micronutrient that serves as an essential enzyme cofactor. Bacteria obtain biotin either through de novo synthesis or by active uptake from exogenous sources. Mycobacteria are unusual amongst bacteria in that their primary source of biotin is through de novo synthesis. Here we review the importance of biotin biosynthesis in the lifecycle of Mycobacteria. Genetic screens designed to identify key metabolic processes have highlighted a role for the biotin biosynthesis in bacilli growth, infection and survival during the latency phase. These studies help to establish the biotin biosynthetic pathway as a potential drug target for new anti-tuberculosis agents.     

Mutant of Escherichia coli with Derepressed Levels of the Biotin Biosynthetic Enzymes

A cross-feeding technique was used to isolate a mutant of Escherichia coli K-12 that excretes 1,000 times more biotin into the growth medium than the parent strain. The mutant has high levels of the biotin biosynthetic enzymes even when grown in the presence of biotin. Desthiobiotin synthetase, the level of which was used as a measure of the biosynthetic activity of the biotin pathway, is not repressed by biotin at the concentration 250,000 times that sufficient to repress the enzyme in the wild type. The mutant gene is cotransducible with argC located at 77 min on the E. coli chromosome.     

MMAR_2770, a new enzyme involved in biotin biosynthesis, is essential for the growth of Mycobacterium marinum in macrophages and zebrafish

Biotin, which functions as an essential cofactor for certain carboxylases and decarboxylases, is synthesized by a multistep pathway in microorganisms and plants. Biotin biosynthesis has not been studied in detail in mycobacteria. In this study, we isolated a mutant of Mycobacterium marinum in which MMAR_2770, a previously uncharacterized gene encoding a predicted short-chain dehydrogenase/reductase, was inactivated. We found that this mutant is a biotin auxotroph that cannot grow in a minimal medium (Sauton) unless biotin is supplemented. Complementation of the mutant with an intact MMAR_2770 or its homolog Rv1882c of Mycobacterium tuberculosis restored the growth of the mutant, suggesting that MMAR_2770 is involved in biotin biosynthesis. We further showed that the mutant was unable to grow in cultured macrophages and was attenuated in zebrafish. Taken together, our results demonstrate that biotin biosynthesis is essential for the growth of mycobacteria in vitro and in vivo and have provided validation for targeting biotin biosynthetic enzymes for antimycobacterial drug development. The potential role of MMAR_2770 in mycobacterial biotin biosynthesis is discussed.     

Optimisation of culture conditions with respect to biotin requirement for the production of recombinant avidin in Pichia pastoris

Due to its very high affinity to biotin, avidin is one of the most widely exploited proteins in modern biotechnological and biomedical applications. Since biotin is an essential vitamin for the growth of many microorganisms, we examined the effect of biotin deficiency on growth for a recombinant Pichia pastoris strain expressing and secreting a recombinant glycosylated avidin. The results showed that biotin deficiency lowers growth rate and biomass yield for P. pastoris. Substitution of biotin in the medium by the two structurally unrelated compounds, aspartic acid and oleic acid, which do not bind to recombinant avidin was analyzed quantitatively. These two compounds had a growth promoting effect in biotin-deficient medium, but did not replace biotin completely. Indeed, in chemostat culture, wash-out occurred after about six liquid residence times and recombinant avidin productivity was lowered. However, addition of low amounts of biotin (20 microg L(-1) of biotin for a cell density of 8 g L(-1)) resulted in stable chemostat cultures on methanol with the production of recombinant biotin-free avidin. The specific avidin production rate was 22 microg g(-1) h(-1) at a dilution rate of 0.06 h(-1).     

Molybdenum cofactor requirement for biotin sulfoxide reduction in Escherichia coli.

The bisC gene of Escherichia coli is tentatively identified as the structural gene for biotin sulfoxide reductase by the isolation of bisC(Ts) mutants that make thermolabile enzyme. The products of four other E. coli genes (chlA, chlB, chlE and chlG) are also needed for enzymatic activity. Mutations previously assigned to the bisA, bisB, and bisD genes belong to genes chlA, chlE, and chlG, respectively. The biotin sulfoxide reductase deficiency of a chlG, mutant is partially reversed by the addition of 10 mM molybdate to the growth medium. Mutational inactivation of the chlD gene reduces the specific activity of biotin sulfoxide reductase about twofold. This effect is reversed by the addition of 1 mM molybdate to the growth medium. The specific activity of biotin sulfoxide reductase is decreased about 30-fold by the presence of tungstate in the growth medium, an effect that has been observed previously with nitrate reductase and other molybdoenzymes. The specific activity of biotin sulfoxide reductase is not elevated in a lysate prepared by derepressing a lambda cI857 chlG prophage. Whereas biotin sulfoxide reductase prepared by sonic extraction of growing cells is almost completely dependent on the presence of a small heat-stable protein resembling thioredoxin, much of the enzyme obtained from lysates of thermoinduced lambda cI857 lysogens does not require this factor.     

Studies on l-Glutamic Acid Fermentation by Microbacterium ammoniaphilum

The present investigation is concerned with the effects of biotin and glucose on glutamic acid fermenation by Microbacterium ammoniaphilum. Both optimal amounts of biotin necessary for maximum growth and maximum accumulation of glutamic acid were determined under the conditoin of various concentration of glucose. As the glucose concentratin was increased, the amounts of biotin required for maximum growth also increased proportionally to the glucose concentrations. The optimal amounts of biotin for maximum accumulation of glutamic acid were smaller than those for maximum growth of cells at any glucose concentration. It is suggested that the process of glutamic acid accumulation is inevitably associated with the process of cell multiplication by both experiments of successive culture of cells grown under the dose of biotin sufficient and deficient for maximum growth.     

Reduction of lactic acid secreted from SV3T3 cells by a serum factor and biotin and its relationship to cell growth

Supplementation of media containing a low concentration (0.15–0.30% $\text{v}\text{>v}$) of calf serum with biotin or a low molecular weight serum growth factor (Peak III) reduces the amount of lactic acid secreted by simian virus 40-transformed 3T3 cells. While biotin and Peak III (which has been tentatively identified as biotin) can stimulate “stationary phase” cells to resume viable cell division, this growth promotion is not due to an alleviation of lactic acid toxicity per se. This conclusion is based on the finding that, although higher concentrations of lactic acid are cytotoxic, lactic acid added at concentrations found during “stationary phase” to cells plated in fresh medium is not growth inhibitory. These results suggest, instead, a possible major role for biotin and Peak III in energy production.     

Increased expression of pyruvate carboxylase and biotin protein ligase increases lysine production in a biotin prototrophic Corynebacterium glutamicum strain

Corynebacterium glutamicum, a Gram‐positive bacterium used for the production of various biochemicals, is naturally a biotin auxotroph. We introduced the biotin genes from Bacillus subtilis on a plasmid, pBIO, into a lysine‐producing derivative (termed AHP‐3) that has been described previously, and achieved biotin prototrophy. We found that AHP‐3, containing pBIO, was able to produce lysine in a medium lacking biotin and that the lysine yield on glucose was similar to what is obtained when using a medium containing biotin. However, there was a decrease in specific growth rate of 20% when the strain was cultivated without biotin, indicating a suboptimal intracellular concentration of biotin. In an attempt to locate the potential bottleneck, we added pimelic acid, an early biotin precursor, and found that growth rate could be restored fully, which demonstrates that the bottleneck is in pimeloyl‐CoA (or pimeloyl‐Acyl Carrier Protein [ACP]) formation. Pyruvate carboxylase (pycA), a biotin‐dependent enzyme needed for lysine biosynthesis and biotin ligase (birA), which is responsible for attaching biotin to pyruvate carboxylase, were overexpressed by replacing the native promoters with the strong superoxide dismutase (sod) promoter, to see whether growth could be restored. Neither pycA nor birA overexpression, whether alone or in combination, had an effect on specific growth rate, but they did have a positive effect on lysine yield, which increased by 55% in the strain overexpressing both enzymes.     

口腔链球菌摄取生物素与口内白色念珠菌生长的关系

为了探讨口腔细菌生态平衡机制,本文体外检测了４株口腔链球菌（Ｓ．ｓａｌｉｖａｒｉｕｓ,Ｓ．ｓａｎｇｕｉｓ,Ｓ．ｍｕｔａｎｓ和Ｓ．ｍｉｔｉｏｒ）和白色念珠菌生长对生物素的依赖性。结果显示白色念珠菌和口腔链球菌的生长绝对依赖生物素,前者最大半数生长需要生物素约１０ｐＭｏｌ／Ｌ,其最大生长率所需生物素约为１００ｐＭｏｌ／Ｌ;而后者最大半数生长需生物素为５２５ｐＭｏｌ／Ｌ。正常人血清和唾液中生物素的含量约为２１２２９４ｐＭｏｌ／Ｌ。生物素饥饿状态下的白色念珠菌和口腔链球菌,以及唾液离心沉淀物（绝大多数为细菌）摄取生物素具温度依赖性,而代谢抑制剂（叠氮化合物、氰化物和醋酸碘）和某些抗生素（杆菌肽、短杆菌肽、万古霉素和二性霉素）具选择性抑制效应,提示生物素的摄取和跨膜转运是一依赖能量的主动过程。用唾液沉淀物和口腔链球菌吸收培养基中的生物素或与白色念珠菌共同培养,显著抑制白色念珠菌的生长。本文首次提供实验证据显示口腔优势菌可能通过竞争生物素等营养成份,抑制白色念珠菌生长,以维持口腔微生物之生态平衡。     

Functional analysis of Sinorhizobium meliloti genes involved in biotin synthesis and transport

External biotin greatly stimulates bacterial growth and alfalfa root colonization by Sinorhizobium meliloti strain 1021. Several genes involved in responses to plant-derived biotin have been identified in this bacterium, but no genes required for biotin transport are known, and not all loci required for biotin synthesis have been assigned. Searches of the S. meliloti genome database in combination with complementation tests of Escherichia coli biotin auxotrophs indicate that biotin synthesis probably is limited in S. meliloti 1021 by the poor functioning or complete absence of several key genes. Although several open reading frames with significant similarities to genes required for synthesis of biotin in gram-positive and gram-negative bacteria were found, only bioB, bioF, and bioH were demonstrably functional in complementation tests with known E. coli mutants. No sequence or complementation evidence was found for bioA, bioC, bioD, or bioZ. In contrast to other microorganisms, the S. meliloti bioB and bioF genes are not localized in a biotin synthesis operon, but bioB is cotranscribed with two genes coding for ABC transporter-like proteins, designated here bioM and bioN. Mutations in bioM and bioN eliminated growth on alfalfa roots and reduced bacterial capacity to maintain normal intracellular levels of biotin. Taken together, these data suggest that S. meliloti normally grows on exogenous biotin using bioM and bioN to conserve biotin assimilated from external sources.     

D-氨基葡萄糖寡聚糖对雏鸡生产性能和主要细菌病防治的研究

目的：使用甲壳素、N-6生命素、氨基葡萄糖盐酸盐防治鸡大肠埃希菌病和沙门菌病。方法：用上述3种产品作为饲料调节剂对雏鸡进行增重试验和抗细菌感染试验。结果：与对照组相比,N-6生命素有促进鸡只生长的作用,同时,上述3种产品能有效地预防和治疗由大肠埃希菌和沙门菌引起的混合感染。结论：N-6生命素防治大肠埃希菌病和沙门菌病效果最好,氨基葡萄糖盐酸盐次之。     

The growth stimulation of SV3T3 cells by transferrin and its dependence on biotin

A critical nutrient for the growth of SV3T3 cells is iron. Iron must be added in the ferrous form or, if in the ferric state, with a suitable complexing agent. Both transferrin and hemoglobin, as iron complexes, will stimulate cell growth in biotin supplemented medium either with low serum (0.15% v/v) or serum-free. The growth stimulation by iron (free or in complexed form) is dependent on the presence of biotin in the medium. These results indicate the importance of transferrin as a serum growth factor.     

Stimulation of guanylate cyclase and RNA polymerase II activities in HeLa cells and fibroblasts by biotin

HeLa cells cultured in a biotin-deficient medium showed reduced rates of protein synthesis, DNA synthesis and growth. Continuous synthesis is required for the increase in DNA synthesis observed upon addition of biotin to cells cultured in biotin-deficient medium. The addition of biotin to the biotin-deficient culture medium increased the activity of guanylate cyclase in both HeLa cells and fibroblasts. Both cell types cultured in biotin deficient medium showed reduced activity of RNA Polymerase II. The exogenous addition of biotin to the biotin-deficient cell cultures also resulted in increased activity of RNA Polymerase II in HeLa cells and fibroblasts. The maximal response was observed in 4 hours. Significant increase in enzyme activity was observed at 10^–8 M biotin in the culture medium. The growth promoting effect of biotin seems to involve stimulations of cellular guanylate cyclase and RNA Polymerase II activity.