Ltc1 is an ER-localized sterol transporter and a component of ER-mitochondria and ER-vacuole contacts.

Organelle contact sites perform fundamental functions in cells, including lipid and ion homeostasis, membrane dynamics, and signaling. Using a forward proteomics approach in yeast, we identified new ER-mitochondria and ER-vacuole contacts specified by an uncharacterized protein, Ylr072w. Ylr072w is a conserved protein with GRAM and VASt domains that selectively transports sterols and is thus termed Ltc1, for Lipid transfer at contact site 1. Ltc1 localized to ER-mitochondria and ER-vacuole contacts via the mitochondrial import receptors Tom70/71 and the vacuolar protein Vac8, respectively. At mitochondria, Ltc1 was required for cell viability in the absence of Mdm34, a subunit of the ER-mitochondria encounter structure. At vacuoles, Ltc1 was required for sterol-enriched membrane domain formation in response to stress. Increasing the proportion of Ltc1 at vacuoles was sufficient to induce sterol-enriched vacuolar domains without stress. Thus, our data support a model in which Ltc1 is a sterol-dependent regulator of organelle and cellular homeostasis via its dual localization to ER-mitochondria and ER-vacuole contact sites

Structural Basis for Lesion Recognition and Commitment to Transcription-Coupled Repair

Transcription-coupled nucleotide excision repair (TC-NER) is a highly conserved pathway that removes bulky lesions in the transcribed genome. Cockayne syndrome B protein (CSB), or its yeast ortholog Rad26, plays important roles in the lesion-recognition steps of TC-NER. How Rad26 distinguishes between RNA polymerase II (Pol II) stalled at a DNA lesion or other obstacles, how a lesion-arrested Pol II is committed to the recruitment of downstream repair factors, and what the fate is of a lesion-arrested Pol II remain unknown. Here, we present cryo-EM structures of Pol II-Rad26 complexes stalled at different obstacles to establish a universal mechanism for the Rad26-mediated recognition of stalled Pol II. We also present a 3.1Å cryo-EM structure of lesion-arrested Pol II-Rad26 bound to a newly identified TC-NER factor, ELOF1/Elf1, that provides insights into its role in the commitment of lesion-arrested Pol II to TC-NER. Finally, we provide biochemical data revealing how Rad26 displaces a lesion-stalled Pol II during TC-NER. These results establish the structural basis of lesion-recognition, commitment to repair, and displacement of lesion-arrested Pol II during TC-NER

Crystal Structures of Mycobacterium tuberculosis CysQ, with Substrate and Products Bound.

In many organisms, 3'-phosphoadenosine 5'-phosphate (PAP) is a product of two reactions in the sulfur activation pathway. The sulfurylation of biomolecules, catalyzed by sulfotransferases, uses 3'-phosphoadenosine 5'-phosphosulfate (PAPS) as a sulfate donor, producing the sulfated biomolecule and PAP product. Additionally, the first step in sulfate reduction for many bacteria and fungi reduces the sulfate moiety of PAPS, producing PAP and sulfite, which is subsequently reduced to sulfide. PAP is removed by the phosphatase activity of CysQ, a 3',5'-bisphosphate nucleotidase, yielding AMP and phosphate. Because excess PAP alters the equilibrium of the sulfur pathway and inhibits sulfotransferases, PAP concentrations can affect the levels of sulfur-containing metabolites. Therefore, CysQ, a divalent cation metal-dependent phosphatase, is a major regulator of this pathway. CysQ (Rv2131c) from Mycobacterium tuberculosis (Mtb) was successfully expressed, purified, and crystallized in a variety of ligand-bound states. Here we report six crystal structures of Mtb CysQ, including a ligand-free structure, a lithium-inhibited state with substrate PAP bound, and a product-bound complex with AMP, phosphate, and three Mg(2+) ions bound. Comparison of these structures together with homologues of the superfamily has provided insight into substrate specificity, metal coordination, and catalytic mechanism

Expression, purification and preliminary crystallographic analysis of Mycobacterium tuberculosis CysQ, a phosphatase involved in sulfur metabolism.

CysQ is part of the sulfur-activation pathway that dephosphorylates 3'-phosphoadenosine 5'-monophosphate (PAP) to regenerate adenosine 5'-monophosphate (AMP) and free phosphate. PAP is the product of sulfate-transfer reactions from sulfotransferases that use the universal sulfate donor 3'-phosphoadenosine 5'-phosphosulfate (PAPS). In some organisms PAP is also the product of PAPS reductases that reduce sulfate from PAPS to sulfite. CysQ from Mycobacterium tuberculosis, which plays an important role in the biosynthesis of sulfated glycoconjugates, was successfully purified and crystallized in 24% PEG 1500, 20% glycerol. X-ray diffraction data were collected to 1.7 Å resolution using a synchrotron-radiation source. Crystals grew in the orthorhombic space group P2₁2₁2₁, with unit-cell parameters a=40.3, b=57.9, c=101.7 Å and with one monomer per asymmetric unit

Crystal Structures of Mycobacterium tuberculosis CysQ, with Substrate and Products Bound.

In many organisms, 3'-phosphoadenosine 5'-phosphate (PAP) is a product of two reactions in the sulfur activation pathway. The sulfurylation of biomolecules, catalyzed by sulfotransferases, uses 3'-phosphoadenosine 5'-phosphosulfate (PAPS) as a sulfate donor, producing the sulfated biomolecule and PAP product. Additionally, the first step in sulfate reduction for many bacteria and fungi reduces the sulfate moiety of PAPS, producing PAP and sulfite, which is subsequently reduced to sulfide. PAP is removed by the phosphatase activity of CysQ, a 3',5'-bisphosphate nucleotidase, yielding AMP and phosphate. Because excess PAP alters the equilibrium of the sulfur pathway and inhibits sulfotransferases, PAP concentrations can affect the levels of sulfur-containing metabolites. Therefore, CysQ, a divalent cation metal-dependent phosphatase, is a major regulator of this pathway. CysQ (Rv2131c) from Mycobacterium tuberculosis (Mtb) was successfully expressed, purified, and crystallized in a variety of ligand-bound states. Here we report six crystal structures of Mtb CysQ, including a ligand-free structure, a lithium-inhibited state with substrate PAP bound, and a product-bound complex with AMP, phosphate, and three Mg(2+) ions bound. Comparison of these structures together with homologues of the superfamily has provided insight into substrate specificity, metal coordination, and catalytic mechanism

Expression, purification and preliminary crystallographic analysis of Mycobacterium tuberculosis CysQ, a phosphatase involved in sulfur metabolism.

CysQ is part of the sulfur-activation pathway that dephosphorylates 3'-phosphoadenosine 5'-monophosphate (PAP) to regenerate adenosine 5'-monophosphate (AMP) and free phosphate. PAP is the product of sulfate-transfer reactions from sulfotransferases that use the universal sulfate donor 3'-phosphoadenosine 5'-phosphosulfate (PAPS). In some organisms PAP is also the product of PAPS reductases that reduce sulfate from PAPS to sulfite. CysQ from Mycobacterium tuberculosis, which plays an important role in the biosynthesis of sulfated glycoconjugates, was successfully purified and crystallized in 24% PEG 1500, 20% glycerol. X-ray diffraction data were collected to 1.7 Å resolution using a synchrotron-radiation source. Crystals grew in the orthorhombic space group P2₁2₁2₁, with unit-cell parameters a=40.3, b=57.9, c=101.7 Å and with one monomer per asymmetric unit

Ltc1 is an ER-localized sterol transporter and a component of ER–mitochondria and ER–vacuole contacts

Organelle contact sites perform fundamental functions in cells, including lipid and ion homeostasis, membrane dynamics, and signaling. Using a forward proteomics approach in yeast, we identified new ER–mitochondria and ER–vacuole contacts specified by an uncharacterized protein, Ylr072w. Ylr072w is a conserved protein with GRAM and VASt domains that selectively transports sterols and is thus termed Ltc1, for Lipid transfer at contact site 1. Ltc1 localized to ER–mitochondria and ER–vacuole contacts via the mitochondrial import receptors Tom70/71 and the vacuolar protein Vac8, respectively. At mitochondria, Ltc1 was required for cell viability in the absence of Mdm34, a subunit of the ER–mitochondria encounter structure. At vacuoles, Ltc1 was required for sterol-enriched membrane domain formation in response to stress. Increasing the proportion of Ltc1 at vacuoles was sufficient to induce sterol-enriched vacuolar domains without stress. Thus, our data support a model in which Ltc1 is a sterol-dependent regulator of organelle and cellular homeostasis via its dual localization to ER–mitochondria and ER–vacuole contact sites