Identification of an operon involved in sulfolipid biosynthesis in Rhodobacter sphaeroides.

Two new mutants of Rhodobacter sphaeroides deficient in sulfolipid accumulation were isolated by directly screening mutagenized cell lines for polar lipid composition by thin-layer chromatography of lipid extracts. A genomic clone which complemented the mutations in these two lines, but not the previously described sulfolipid-deficient sqdA mutant, was identified. Sequence analysis of the relevant region of the clone revealed three, in tandem open reading frames, designated sqdB, ORF2, and sqdC. One of the mutants was complemented by the sqdB gene, and the other was complemented by the sqdC gene. Insertional inactivation of sqdB also inactivated sqdC, indicating that sqdB and sqdC are cotranscribed. The N-terminal region of the 46-kDa putative protein encoded by the sqdB gene showed slight homology to UDP-glucose epimerase from various organisms. The 30-kDa putative protein encoded by ORF2 showed very striking homology to rabbit muscle glycogenin, a UDP-glucose utilizing, autoglycosylating glycosyltransferase. The 26-kDa putative protein encoded by the sqdC gene was not homologous to any protein of known function.     

Disruption of a gene essential for sulfoquinovosyldiacylglycerol biosynthesis in Sinorhizobium meliloti has no detectable effect on root nodule symbiosis

The sulfolipid sulfoquinovosyldiacylglycerol is commonly found in the thylakoid membranes of photosynthetic bacteria and plants. While there is a good correlation between the occurrence of sulfolipid and photosynthesis, a number of exceptions are known. Most recently, sulfoquinovosyldiacylglycerol was discovered in the non-photosynthetic, root nodule-forming bacterium Sinorhizobium meliloti. This discovery raised the questions of the phylogenetic origin of genes essential for the biosynthesis of this lipid in S. meliloti and of a function of sulfolipid in root nodule symbiosis. To begin to answer these questions, we isolated and inactivated the sqdB gene of S. meliloti. This gene and two other genes located directly 3' of sqdB are highly similar to the sqdB, sqdC, and sqdD genes known to be essential for sulfolipid biosynthesis in the photosynthetic, purple bacterium Rhodobacter sphaeroides. This observation confirms the close phylogenetic kinship between these two species. Furthermore, the reduced similarity of sqdB to the plant ortholog SQD1 of Arabidopsis thaliana does not support a previous sqd gene transfer from the plant as a consequence of close symbiosis. A sulfolipid-deficient mutant of S. meliloti disrupted in sqdB is capable of inducing functional nodules and does not show an obvious disadvantage under different laboratory culture conditions. Thus far, no specific function can be assigned to bacterial sulfolipid, in either nodule-associated or free-living cells. S. meliloti contains a rich set of polar membrane lipids some of which, including sulfolipid, may become critical only under growth conditions that still need to be discovered.     

A cyanobacterial gene, sqdX, required for biosynthesis of the sulfolipid sulfoquinovosyldiacylglycerol

The sulfolipid sulfoquinovosyldiacylglycerol is present in the photosynthetic membranes of plants and many photosynthetic bacteria. A novel gene, sqdX, essential for sulfolipid biosynthesis in the cyanobacterium Synechococcus sp. strain PCC7942 is proposed to encode the cyanobacterial sulfolipid synthase catalyzing the last reaction of the pathway.     

Elucidation and chemical modulation of sulfolipid-1 biosynthesis in Mycobacterium tuberculosis

Mycobacterium tuberculosis possesses unique cell-surface lipids that have been implicated in virulence. One of the most abundant is sulfolipid-1 (SL-1), a tetraacyl-sulfotrehalose glycolipid. Although the early steps in SL-1 biosynthesis are known, the machinery underlying the final acylation reactions is not understood. We provide genetic and biochemical evidence for the activities of two proteins, Chp1 and Sap (corresponding to gene loci rv3822 and rv3821), that complete this pathway. The membrane-associated acyltransferase Chp1 accepts a synthetic diacyl sulfolipid and transfers an acyl group regioselectively from one donor substrate molecule to a second acceptor molecule in two successive reactions to yield a tetraacylated product. Chp1 is fully active in vitro, but in M. tuberculosis, its function is potentiated by the previously identified sulfolipid transporter MmpL8. We also show that the integral membrane protein Sap and MmpL8 are both essential for sulfolipid transport. Finally, the lipase inhibitor tetrahydrolipstatin disrupts Chp1 activity in M. tuberculosis, suggesting an avenue for perturbing SL-1 biosynthesis in vivo. These data complete the SL-1 biosynthetic pathway and corroborate a model in which lipid biosynthesis and transmembrane transport are coupled at the membrane-cytosol interface through the activity of multiple proteins, possibly as a macromolecular complex.     

Synthesis of different nucleoside 5'-diphospho-sulfoquinovoses and their use for studies on sulfolipid biosynthesis in chloroplasts

6-Sulfo-alpha-D-quinovopyranosyl phosphate was reacted with different nucleoside monophosphate morpholidates to form ADP-, CDP-, GDP- and UDP-sulfoquinovose. Analytical and preparative HPLC of these nucleotides was performed on reversed-phase columns using volatile buffer systems as eluant. The isolated compounds were characterized by NMR spectroscopy (except the CDP derivative) and used for an investigation of sulfolipid biosynthesis by chloroplasts. For this purpose intact spinach chloroplasts were biosynthetically preloaded with radioactive diacylglycerol to provide a sulfoquinovosyl acceptor. When sulfosugar nucleotides were added to such prelabelled intact organelles, the background levels of sulfolipid biosynthesis did not rise. On the other hand, after osmotic shock of prelabelled chloroplasts sulfolipid labelling was significantly increased by the addition of UDP- or GDP-sulfoquinovose. The same stimulation was observed with isolated envelope membranes, and UDP-sulfoquinovose proved to be twice as active as the GDP derivative. From these results it was concluded that the final step in sulfolipid biosynthesis is catalyzed by a UDP-sulfoquinovose: 1,2-diacylglycerol 3-O-alpha-D-sulfoquinovosyltransferase. This chloroplast enzyme cannot use exogenously supplied sulfosugar nucleotides, which as membrane-impermeable compounds are expected to be formed in vivo within chloroplasts.     

Enzymatic Characteristics of UDP-sulfoquinovose: Diacylglycerol Sulfoquinovosyltransferase from Chloroplast Envelopes*

Envelope membranes from chloroplasts contain UDP-sulfoquinovose: diacylglycerol sulfoquinovosyltransferase which catalyses the final step in sulfolipid assembly. In situ produced diacylglycerol served as radioactive acceptor to measure enzymatic activity. With this assay, several enzymatic parameters were investigated. The enzyme, which has maximal activity at pH 7.5, was stimulated by magnesium ions due to a decrease of the K_m for uridine 5′-diphospho-sulfoquinovose from 80 pM (no magnesium) to 10 μM (5 mM magnesium). This stimulation had a K_m of 0.7 mM magnesium and may be relevant in light/dark modulation of the enzymatic activity. The lower efficiency of guanosine 5′-diphospho-sulfoquinovose observed before can be ascribed to a higher K_m of this sugar nucleotide (400 μM). Under optimized and linearized conditions the sulfoquinovosyltransferase displayed about 10% of the activity of the UDP-galactose: diacylglycerol galactosyltransferase which competes in the same membrane system for diacylglycerols. Addition of acidic lipids, such as sulfolipid and phosphatidylglycerol, to envelope membranes resulted in an inhibition of the sulfoquinovosyltransferase, whereas the galactosyltransferase was not affected. In vivo this may contribute to an adjustment of the sulfolipid proportion in plastid membranes. In contrast to the galactosyltransferase the sulfoquinovosyltransferase did not discriminate against the dipalmitoyl molecular species of diacylglycerol when offered together with the oleoyl-palmitoyl species. Under conditions when oleoyl-palmitoyl-and dipalmitoyl-diacylglycerols were synthesized with concurrent conversion to monogalactosyl and sulfoquinovosyl diacylglycerol, the sulfolipid was highly enriched in the fully saturated species. This may explain the occurrence of dipalmitoyl species in sulfolipids, as found in many plants.     

X-Linked juvenile retinoschisis associated with a 4-base pair insertion at codon 55 of the XLRS1 gene

X-linked juvenile retinoschisis (RS) is a bilateral vitreoretinal disorder with no known cure. The gene responsible for the disease was recently isolated by positional cloning methods and a spectrum of mutations has been described in families with RS pathology. In this report, we screened six sporadic cases of RS for mutations in the RS gene to understand the etiology of isolated cases. Our extensive studies revealed a novel 4 bp insertion in one family and the remaining families did not show mutations in the RS gene. This mutation altered the reading frame including codon 55 resulting in nine aberrant amino acid residues. The unaffected mother did not contain this mutation. Additionally, it was not found in 60 normal control chromosomes, suggesting that the insertion mutation is disease related in the family analyzed.     

Sulfolipid metabolism in chlorella

When S-deficient cells of Chlorella cllipsoidea were incubated in radio-sulfate in light or in aerobic darkness for 1 hour, equal amounts of radioactivity were found in sulfolipid and glutathione but none was detected in sulfoquinovosyl glycerol which is one of the major S-compounds in this alga. No assimilation of radiosulfate was observed under anaerobic darkness.

To elucidate the function of sulfolipid in algal cells uniformly ³⁵S-labeled Chlorella cells were transferred to S-deficient culture medium or unlabeled normal culture medium and the changes of radioactivity in sulfolipid and the related compounds were followed. A) On incubating ³⁵S-labeled algal cells in S-deficient medium under photosynthetic conditions, the amounts of radioactivity in sulfate, sulfoquinovosyl glycerol and sulfolipid decreased rapidly. B) When ³⁵S-labeled cells were cultured photoautotrophically in unlabeled medium, no decrease of radioactivity was observed in sulfoquinovosyl glycerol and sulfolipid. C) A decrease of ³⁵S-sulfolipid and an increase of ³⁵S-sulfoquinovosyl glycerol were observed when the uniformly ³⁵S-labeled algal cells were illuminated in CO₂-free air.

When S-deficient Chlorella cells were incubated in ³⁵S-sulfolipid under photosynthetic conditions, significant radioactivity was found in the insoluble fraction of the cells. A similar result was observed when normal Chlorella cells were incubated in ¹⁴C-sulfolipid and CO₂-free air.

It is inferred from these observations that sulfolipid is a reservoir of sulfur and carbon compounds.

In order to ascertain if the sulfolipid is involved in the mechanism of photosynthetic oxygen evolution, the rate of photosynthesis was measured during the incubation of ³⁵S-labeled cells in a S-deficient medium. Parallelism was not observed between the rate of photosynthetic activity and the decrease of sulfolipid.

     

Events surrounding the early development of Euglena chloroplasts. 15. Origin of plastid thylakoid polypeptides in wild-type and mutant cells.

Techniques are described for the isolation of plastid thylakoid membranes from light-grown and dark-grown cells of Euglena gracilis var. bacillaris, and from mutants affecting plastid development. These membranes, which have minimal contamination with other cell fractions, are localized in sucrose gradients by using the thylakoid membrane sulfolipid as a specific marker. The plastid thylakoid membrane polypeptides isolated from these membranes were separated on SDS polyacrylamide gels and yielded patterns containing 30-40 polypeptides. Light-grown strain Z gave patterns identical with bacillaris. Since the plastid thylakoid polypeptide patterns obtained from dark-grown wild-type cells and from a bleached mutant W3BUL in which plastid DNA is undetectable are identical, it appears that the proplastid thylakoid polypeptides of wild-type cannot be coded in plastid DNA and are probably coded in nuclear DNA. The plastid thylakoid polypeptide patterns obtained from various dark-grown mutants, making large but abnormal chloroplasts, show a correlation between the amount of chlorophyll formed and the amount of a plastid thylakoid polypeptide thought to be associated wtth one of the pigment-protein light-harvesting complexes. Treatment with SAN 9789 (4-chloro-5-(methylamino)-2(alpha, alpha, alpha,-trifluoro-m-tolyl)-3-(2H(pyridazinone) known to block carotenoid synthesis at the level of phytoene, causes a progressive loss of all plastid thylakoid polypeptides during growth in darkness and results in the establishment of a new, lowere steady-state level of sulfolipid. At least ten of the plastid thylakoid polypeptides become labeled when isolated chloroplasts are supplied with radioactive amono acids; of these six are undectable in W3BUL and are, therefore, candidates for coding by plastid DNA.     

Uridine-diphospho-sulfoquinovose: diacylglycerol sulfoquinovosyltransferase activity is concentrated in the inner membrane of chloroplast envelopes

In experiments on the assembly of the sulfolipid sulfoquinovosyl diacylglycerol in envelope membranes of chloroplasts, UDP-sulfoquinovose (UDPS) was used with highest efficiency, and the corresponding enzyme, UDP-sulfoquinovose:diacylglycerol sulfoquinovosyltransferase, was partially characterized (E. Heinz et al., 1989, Eur J Biochem 184: 445–453). Here, we identified ³⁵S- and ³³P-labelled UDPS from various photosynthetically active organisms, suggesting that the sulfosugar nucleotide used for sulfolipid biosynthesis throughout the plant kingdom, including phototrophic bacteria, may indeed be UDPS. For attribution of the sulfolipid synthase to one of the two plastidial envelope membranes, these membranes were isolated from pea and spinach chloroplasts. The sulfoquinovosyltransferase was localized in the inner membrane of envelopes, which also contains the competing UDP-galactose:diacylglycerol galactosyltransferase. In contrast to the sulfoquinovosyltransferase, a substantial proportion of the galactosyltransferase was found in the outer membranes of envelopes from pea chloroplasts. Received: 6 October 1997 / Accepted: 31 January 1998     

RGD-containing peptides inhibit the synthesis of myelin-like membrane by cultured oligodendrocytes

A synthetic peptide derived from the fibronectin cell-binding domain, GRGDSP, inhibits the adhesion of rat oligodendrocytes to a number of substrates. However, while GRGDSP inhibited the adhesion of cells in a short term adhesion assay, the presence of the peptide did not prevent cells from adhering and thriving in longer term culture. The morphological characteristics of individual cells cultured with 0.1 mg/ml GRGDSP were similar to untreated cultures; small rounded cell bodies radiating numerous fine processes. Peptide-treated cultures were inhibited in their ability to produce myelin specific components. The characteristic developmental peak in sulfolipid synthesis which occurs both in vivo and in vitro was completely inhibited when cells were cultured with GRGDSP. In addition, the synthesis of myelin basic protein was inhibited. Ultrastructurally, cells treated with GRGDSP showed a greatly reduced number of multilamellar myelin-like membrane figures than cells grown without peptide or those grown with GRADSP. Cultured oligodendrocytes did not become sensitive to inhibition of sulfolipid synthesis by GRGDSP until a period immediately preceding the peak in sulfolipid biosynthesis. The effects of pretreatment with peptide for 5 d before this time were completely reversible. Pretreatment which extended into the time of peak myelin synthesis resulted in permanent impairment in the cell's ability to synthesize sulfolipid. The oligodendrocyte's ability to synthesize a myelin-like membrane in culture is, in part, inherent since it occurs in the absence of neurons. The present results indicate that myelin membrane production is also subject to external control since it appears that occupancy of an RGD-dependent cell surface receptor during a critical period of in vitro development is required for the oligodendrocyte to produce myelin-like membrane.     

The organization of genes tightly linked to the Ha locus in Aegilops tauschii, the D-genome donor to wheat.

The grain hardness locus, Ha, is located at the distal end of the short arm of chromosome 5D in wheat. Three polypeptides, puroindoline-a, puroindoline-b, and grain softness protein (GSP-1), have been identified as components of friabilin, a biochemical marker for grain softness, and the genes for these polypeptides are known to be tightly linked to the Ha locus. However, this region of the chromosome 5D has not been well characterized and the physical distance between the markers is not known. Separate lambda clones containing the puroindoline-a gene and the puroindoline-b gene have been isolated from an Aegilops tauschii (the donor of the D genome to wheat) genomic lambda library and investigated. Considerable variation appears to exist in the organization of the region upstream of the gene for puroindoline-b among species closely related to wheat. Using in situ hybridization the genes for puroindoline-a, -b, and GSP-1 were demonstrated to be physically located at the tip of the short arm of chromosome 5 of A. tauschii. Four overlapping clones were isolated from a large-insert BAC library constructed from A. tauschii and of these one contained genes for all of puroindoline-a, puroindoline-b, and GSP-1. The gene for puroindoline-a is located between the other two genes at a distance no greater than approximately 30 kb from either gene. The BAC clone containing all three known genes was used to screen a cDNA library constructed from hexaploid wheat and cDNAs that could encode novel polypeptides were isolated.     

Questions remaining in sulfolipid biosynthesis: a historical perspective

The plant sulfolipid sulfoquinovosyldiacylglycerol was discovered by A.A. Benson in the late 1950s. The increasing availability of radioisotope-containing biological substrates such as ³⁵S-sulfate provided the means to discover novel biological compounds and to sketch out their biosynthetic pathways. During this time the structure of sulfolipid with its 6-deoxy-6-sulfo-α-d-glucose (sulfoquinovose) headgroup was determined. Immediately, the origin of this unusual biological sulfonic acid mystified the scientific community and several proposals for its biosynthesis were developed and tested. Strong supportive evidence for the nucleotide pathway of sulfolipid biosynthesis became available with the discovery of the bacterial and plant genes encoding the enzymes of sulfolipid biosynthesis during the 1990s. This latter work was based on the foundations laid by A.A. Benson and confirmed one initial hypothesis on sulfolipid biosynthesis. An abbreviated summary of the turning points in defining the mechanism for sulfolipid biosynthesis and remaining issues in sulfolipid biochemistry are provided.     

Uniqueness of Entamoeba sulfur metabolism: sulfolipid metabolism that plays pleiotropic roles in the parasitic life cycle

Sulfur metabolism is ubiquitous and terminally synthesizes various biomolecules that are crucial for organisms, such as sulfur‐containing amino acids and co‐factors, sulfolipids and sulfated saccharides. Entamoeba histolytica, a protozoan parasite responsible for amoebiasis, possesses the unique sulfur metabolism features of atypical localization and its terminal product being limited to sulfolipids. Here, we present an overall scheme of E. histolytica sulfur metabolism by relating all sulfotransferases and sulfatases to their substrates and products. Furthermore, a novel sulfur metabolite, fatty alcohol disulfates, was identified and shown to play an important role in trophozoite proliferation. Cholesteryl sulfate, another synthesized sulfolipid, was previously demonstrated to play an important role in encystation, a differentiation process from proliferative trophozoite to dormant cyst. Entamoeba survives by alternating between these two distinct forms; therefore, Entamoeba sulfur metabolism contributes to the parasitic life cycle via its terminal products. Interestingly, this unique feature of sulfur metabolism is not conserved in the nonparasitic close relative of Entamoeba, Mastigamoeba, because lateral gene transfer‐mediated acquisition of sulfatases and sulfotransferases, critical enzymes conferring this feature, has only occurred in the Entamoeba lineage. Hence, our findings suggest that sulfolipid metabolism has a causal relationship with parasitism.     

Lysosomal sulfoglycolipid storage in the kidneys of mice deficient for arylsulfatase A (ASA) and of double-knockout mice deficient for ASA and galactosylceramide synthase

The inherited deficiency of arylsulfatase A (ASA) causes lysosomal accumulation of sulfoglycolipids (mainly sulfo-galactosylceramide, S-GalCer ) and leads to metachromatic leukodystrophy in humans. Among visceral organs, kidneys are particularly affected. In the present study, the regional distribution and temporal development of sulfoglycolipid storage in kidneys of ASA-/- mice was investigated histochemically (alcian blue) and ultrastructurally. Furthermore, the sulfoglycolipid storage was examined in kidneys of double-knockout mice, which are incapable of: (a) degrading any sulfolipids (ASA-/-) and (b) synthesizing the major sulfolipid S-GalCer because of deficiency for galactosylceramide synthase (CGT), with the aim to search for additional ASA substrates. In ASA-/- mice, the nephron segments could be ranged in the order of decreasing sulfolipid storage: thin limbs of long-looped nephrons approximately thick ascending limbs > distal convoluted tubules > collecting ducts approximately short thin limbs. Macula densa and proximal tubules were unaffected. In ASA-/-/CGT-/- mice, the long thin limbs and distal convoluted tubules resembled those of ASA-/-/CGT+/+ mice, while the other segments showed less storage. The results suggest that the turnover of sulfolipids in general is highest in the distal nephron except macula densa, and that long thin limbs and distal convoluted tubules are the main sites for turnover of a minor sulfolipid species, which is known to be synthesized in the kidney of CGT-/- mice.     

Localization of sulfolipid labeling within cells and chloroplasts

Spinach chloroplasts were purified on gradients of Percoll which preserved envelope impermeability and CO₂-dependent oxygen evolution in the light. Application of ³⁵SO₄ to purified chloroplasts resulted in a light-dependent labeling of a lipid component which was indentified as sulfoquinovosyl diacylglycerol. Fractionation of chloroplasts showed that after 5 min of labeling most of the newly synthesized sulfolipid was present in thylakoids. Only a small percentage was recovered from the envelopes. Molecular species from envelopes and thylakoids were identical. The molecular species did not change during incubation times ranging from 5 min up to 4.5 h. Mesophyll protoplasts from ³⁵SO₄-labeled oat primary leaves were gently disrupted and separated into organelles by sucrose gradient centrifugation. Labeled sulfolipid was located almost exclusively in the chloroplasts. This, in combination with the experiments carried out with isolated chloroplasts, indicates that the final assembly steps in the biosynthesis of sulfolipid are confined to the chloroplasts.     

Effects of triiodothyronine on the synthesis of sulfolipids by oligodendrocyte-enriched glial cultures

Glial cultures were obtained from the brains of 1-week-old rats and were grown in a chemically defined, serum-free medium. We investigated the development of oligodendrocytes in these cultures and the synthesis of sulfolipids in the presence and absence of triiodothyronine (T3) in the medium: (1) In the presence of T3, the incorporation of [35S]sulfate into sulfolipids exhibited a developmental profile which is comparable to that found in the developing brain in vivo. A sharp peak of sulfolipid synthesis was observed at day 5 in vitro, which is equivalent to day 12 after birth. As observed in vivo, the percentage of label incorporated into sulfogalactosyldiradylglycerols decreased with time in culture. (2) Addition of T3 to the medium stimulated sulfolipid synthesis by oligodendrocytes in a dose-related manner (optimal T3 concentration, 30 nM). The hormone also enhanced the rates of cholesterogenesis and lipogenesis but to a lesser extent than sulfolipid synthesis. (3) The temporary omission of T3 from the medium resulted in lower rates of sulfolipid synthesis that could not be restored by readdition of T3. This inhibitory effect was most pronounced if the hormone was omitted from the medium on days 2 and 3 in culture. (4) Omission of T3 also resulted in the development of fewer oligodendrocytes in the cultures. Our results show that T3 is essential for the development of oligodendrocytes in our neurone-free culture system. They also indicate that the stimulation of myelination by thyroid hormones can, at least partially, be explained as a direct effect of T3 on oligodendrocytes, independent of an effect of T3 on neuronal growth.     

Changes in fatty acid composition of sulfolipid and phospholipids during maturation of alfalfa

Lipids were extracted from alfalfa samples collected at intervals over the growing season and were fractionated to yield pure sulfolipid. In the sulfolipid and in a phospholipid fraction the major fatty acids were palmitic, linolenic, and linoleic, of which the palmitic acid increased in proportion during the season while the proportion of linolenic acid dropped. The sulfolipid contained more linolenic acid and less palmitic and linoleic acids than the phospholipids, and had a greater rate of change of fatty acid composition.