Your search keyword '"Paiva, Sandra"' showing total 12 results

1. Carboxylic Acids Plasma Membrane Transporters in Saccharomyces cerevisiae

Author

Casal, Margarida, Queirós, Odília, Talaia, Gabriel, Ribas, David, Paiva, Sandra, COHEN, IRUN R., Series editor, LAJTHA, ABEL, Series editor, LAMBRIS, JOHN D., Series editor, PAOLETTI, RODOLFO, Series editor, Ramos, José, editor, Sychrová, Hana, editor, and Kschischo, Maik, editor

Published

2016

2. Functional analysis of Kluyveromyces lactis carboxylic acids permeases: heterologous expression of KlJEN1 and KlJEN2 genes

Author

Queirós, Odília, Pereira, Leonor, Paiva, Sandra, Moradas-Ferreira, Pedro, and Casal, Margarida

Published

2007

3. Pinpointing intracellular trafficking determinants in the Jen1 yeast lactate transporter by domain swap

Author

Rocha, Gabriel Azevedo Carreira Talaia da, Diallinas, George, Casal, Margarida, Paiva, Sandra, and Universidade do Minho

Subjects

Transporters, Yeast

Abstract

The intracellular trafficking of plasma membrane proteins, such as receptors and transporters, in eukaryotic cells is a highly regulatedprocess. Changing environment conditions (nutrients, substrates, hormones) can trigger endocytosis of unwanted transporters. The monocarboxylate transporter Jen1p of the yeast Saccharomyces cerevisiae has proven to be an excellent model system forgenetically dissecting mechanisms that regulate trafficking of a eukaryotic PM protein, according to physiological constraints. Ourgroup has demonstrated that glucose acts as a signal to induce endocytic down-regulation of Jen1 within minutes, a processdependent both on phosphorylation and ubiquitylation (Paiva et al, 2002; Paiva et al, 2009).In an attempt to identify domains that are important for the subcellular localization, activity and turnover of Jen1p, domain swapexperiments were carried out. The hybridtransporter genes also carry a C-terminal fusion with the ORF of the green fluorescent protein (GFP), which enabled the in vivomicroscopic investigation of the trafficking, membrane localization and turnover of Jen1p protein. This strategy is ideal to identify whether the Jen1 terminals include molecular determinants necessary and sufficient for glucoseelicitedendocytosis and sorting to endosomes. Studies regarding the rates of endocytosis and/or direct sorting of the chimerictransporters, under various physiological conditions, will be presented. Uptake assays using radiolabeled lactic acid were also employed to measure the activity of the chimeric transporters, under specific conditions.

Published

2011

4. Yeast as a tool to express sugar acid transporters with biotechnological interest.

Author

Ribas, David, Sá-Pessoa, Joana, Soares-Silva, Isabel, Paiva, Sandra, Nygård, Yvonne, Ruohonen, Laura, Penttilä, Merja, and Casal, Margarida

Subjects

YEAST, ORGANIC compounds, MEMBRANE transport proteins, SACCHAROMYCES cerevisiae, MOLECULAR docking

Abstract

Sugar acids can be used as platform chemicals to generate primary building blocks of industrially relevant products. Microbial production of these organic compounds at high yields requires the engineering of the enzymatic machinery and the presence of plasma membrane transporters able to export them outside the cells. In this study, several yeast carboxylic acid transporters belonging to the Jen family were screened for the transport of biotechnologically relevant sugar acids, namely gluconic, saccharic, mucic, xylaric and xylonic acid, and functionally characterised in Saccharomyces cerevisiae. We show that Jen permeases are capable of transporting most of these sugar acids, although with different specificities. Saccharate is a substrate of the transporters ScJen1-S271Q and KlJen2, gluconate of CaJen2 and KlJen2, and xylarate and mucate of CaJen2. A molecular docking approach of these transporters identified the residues that play a major role in the substrate binding of these sugar acids, namely R188 (ScJen1), R122 (CaJen2) and R127 (KlJen2), all equivalent residues (TMS II). The identification of Jen members as sugar acid transporters can contribute to engineering efficient microbial cell factories with increased sugar acid production, as the ScJen1 is able to promote substrate efflux. [ABSTRACT FROM AUTHOR]

Published

2017

5. Utilization of green fluorescent protein as a marker for studying the expression and turnover of the monocarboxylate permease Jen1p of Saccharomyces cerevisiae

Author

Paiva, Sandra, Kruckeberg, Arthur L., Casal, Margarida, and Universidade do Minho

Subjects

0303 health sciences, Science & Technology, 030302 biochemistry & molecular biology, Ubiquitination, Transport, Cell Biology, Biochemistry, Yeast, Endocytosis, 03 medical and health sciences, Molecular Biology, Secretion, 030304 developmental biology

Abstract

Green Fluorescent protein (GFP) from Aequorea ictoria was used as an in vivo reporter protein when fused to the C-terminus of the Jen1 lactate permease of Saccharomyces cerevisiae. The Jen1 protein tagged with GFP is a functional lactate transporter with a cellular abundance of 1670 molecules/cell, and a catalyticcentre activity of 123 s-1. It is expressed and tagged to the plasma membrane under induction conditions. The factors involved in proper localization and turnover of Jen1p were revealed by expression of the Jen1p-GFP fusion protein in a set of strains bearing mutations in specific steps of the secretory and endocytic pathways. The chimaeric protein Jen1p-GFP is targeted to the plasma membrane via a Sec6-dependent process; upon treatment with glucose, it is endocytosed via END3 and targeted for degradation in the vacuole. Experiments performed in a Ddoa4 mutant strain showed that ubiquitination is associated with the turnover of the permease., FEBS - short-term fellowship., Portugal - Programa Operacional “Ciência, Tecnologia, Inovação” (POCTI) - POCTI/1999/BME/36 625., Portuguese Government - PRAXIS XXI-BD/1898/98.

Published

2002

6. The putative monocarboxylate permeases of the yeast Saccharomyces cerevisiae do not transport monocarboxylic acids across the plasma membrane

Author

Makuc, Judita, Paiva, Sandra, Schauen, Matthias, Krämer, Reinhard, André, Bruno, Casal, Margarida, Leão, Cecília, Boles, Eckard, and Universidade do Minho

Subjects

Pyruvate, Science & Technology, Functional analysis, Acetate, Monocarboxylate transport, Lactate, MCT genes, Yeast, Mitochondria

Abstract

We have characterized the monocarboxylate permease family of Saccharomyces cerevisiae comprising five proteins. We could not find any evidence that the monocarboxylate transporter-homologous (Mch) proteins of S. cerevisiae are involved in the uptake or secretion of monocarboxylates such as lactate, pyruvate or acetate across the plasma membrane. Ayeast mutant strain deleted for all five MCH genes exhibited no growth defects on monocarboxylic acids as the sole carbon and energy sources. Moreover, the uptake and secretion rates of monocarboxylic acids were indistinguishable from the wildtype strain. Additional deletion of the JEN1 lactate transporter gene completely blocked uptake of lactate and pyruvate. However, uptake of acetate was not even affected after the additional deletion of the gene YHL008c, which had been proposed to code for an acetate transporter. The mch1–5 mutant strain showed strongly reduced biomass yields in aerobic glucose-limited chemostat cultures, pointing to the involvement of Mch transporters in mitochondrial metabolism. Indeed, intracellular localization studies indicated that at least some of the Mch proteins reside in intracellular membranes. However, pyruvate uptake into isolated mitochondria was not affected in the mch1–5 mutant strain. It is concluded that the yeast monocarboxylate transporter-homologous proteins perform other functions than do their mammalian counterparts., União Europeia (UE) – grant BIO4-CT97-2294 (EUROFAN2)., Fundação para a Ciência e a Tecnologia (FCT) - PRAXIS XXI-BD/1898/98.

Published

2001

7. The Debaryomyces hansenii carboxylate transporters Jen1 homologues are functional in Saccharomyces cerevisiae.

Author

Soares-Silva, Isabel, Ribas, David, Foskolou, Iosifina P., Barata, Beatriz, Bessa, Daniela, Paiva, Sandra, Queirós, Odília, and Casal, Margarida

Subjects

DEBARYOMYCES hansenii, CARBOXYLATES, SACCHAROMYCES cerevisiae, HOMOLOGY (Biology), CARBOXYLIC acids

Abstract

We have functionally characterized the four Saccharomyces cerevisiae (Sc) Jen1 homologues of Debaryomyces hansenii (Dh) by heterologous expression in S. cerevisiae. Debaryomyces hansenii cells display mediated transport for the uptake of lactate, acetate, succinate and malate. DHJEN genes expression was detected by RT-PCR in all carbon sources assayed, namely lactate, succinate, citrate, glycerol and glucose. The heterologous expression in the S. cerevisiae W303-1A jen1Δ ady2Δ strain demonstrated that the D. hansenii JEN genes encode four carboxylate transporters. DH27 gene encodes an acetate transporter (Km 0.94 ± 0.17 mM; Vmax 0.43 ± 0.03 nmol s-1 mg-1), DH17 encodes a malate transporter (Km 0.27 ± 0.04 mM; Vmax 0.11 ± 0.01 nmol s-1 mg-1) and both DH18 and DH24 encode succinate transporters with the following kinetic parameters, respectively, Km 0.31 ± 0.06 mM; Vmax 0.83 ± 0.04 nmol s-1 mg-1 and Km 0.16 ± 0.02 mM; Vmax 0.19 ± 0.02 nmol s-1 mg-1. Surprisingly, no lactate transporter was found, although D. hansenii presents a mediated transport for this acid. This work advanced the current knowledge on yeast carboxylate transporters by characterizing four new plasma membrane transporters in D. hansenii. [ABSTRACT FROM AUTHOR]

Published

2015

8. SATP (YaaH), a succinate-acetate transporter protein in Escherichia coli.

Author

SÁ-PESSOA, Joana, PAIVA, Sandra, RIBAS, David, SILVA, Inês Jesus, VIEGAS, Sandra Cristina, ARRAIANO, Cecília Maria, and CASAL, Margarida

Subjects

*ESCHERICHIA coli, *CARRIER proteins, *ACETIC acid, *SUCCINIC acid, *AMINO acid residues, *BACTERIA

Abstract

In the present paper we describe a new carboxylic acid transporter in Escherichia coli encoded by the gene yaaH. In contrast to what had been described for other YaaH family members, the E. coli transporter is highly specific for acetic acid (a monocarboxylate) and for succinic acid (a dicarboxylate), with affinity constants at pH 6.0 of 1.24≠0.13 mM for acetic acid and 1.18≠ 0.10 mM for succinic acid. In glucose-grown cells the ΔyaaH mutant is compromised for the uptake of both labelled acetic and succinic acids. YaaH, together with ActP, described previously as an acetate transporter, affect the use of acetic acid as sole carbon and energy source. Both genes have to be deleted simultaneously to abolish acetate transport. The uptake of acetate and succinate was restored when yaaH was expressed in trans in ΔyaaH ΔactP cells. We also demonstrate the critical role of YaaH amino acid residues Leu131 and Ala164 on the enhanced ability to transport lactate. Owing to its functional role in acetate and succinate uptake we propose its assignment as SatP: the Succinate-Acetate Transporter Protein. [ABSTRACT FROM AUTHOR]

Published

2013

9. The transport of carboxylic acids and important role of the Jen1p transporter during the development of yeast colonies.

Author

PAIVA, Sandra, STRACHOTOVÁ, Dita, KUČEROVÁ, Helena, HLAVÁČEK, Otakar, MOTA, Sandra, CASAL, Margarida, PALKOVÁ, Zdena, and VÁCHOVÁ, Libuše

Subjects

*BIOCHEMICAL substrates, *YEAST, *AMMONIA manufacturing, *CELL metabolism, *QUORUM sensing, *LACTIC acid

Abstract

On solid substrates, yeast colonies pass through distinct developmental phases characterized by the changes in pH of their surroundings from acidic to nearly alkaline and vice versa. At the beginning of the alkali phase colonies start to produce ammonia, which functions as a quorum-sensing molecule inducing the reprogramming of cell metabolism. Such reprogramming includes, among others, the activation of several plasma membrane transporters and is connected with colony differentiation. In the present study, we show that colony cells can use two transport mechanisms to import lactic acid: a 'saturable' component of the transport, which requires the presence of a functional Jen1p transporter, and a 'non-saturable' component (diffusion) that is independent of Jen1p. During colony development, the efficiency of both transport components changes similarly in central and outer colonial cells. Although the lactate uptake capacity of central cells gradually decreases during colony development, the lactate uptake capacity of outer cells peaks during the alkali phase and is also kept relatively high in the second acidic phase. This lactate uptake profile correlates with the localization of the Jen1p transporter to the plasma membrane of colony cells. Both lactic acid uptake mechanisms are diminished in sok2 colonies where JEN1 expression is decreased. The Sok2p transcription factor may therefore be involved in the regulation of non-saturable lactic acid uptake in yeast colonies. [ABSTRACT FROM AUTHOR]

Published

2013

10. Transport of carboxylic acids in yeasts.

Author

Casal, Margarida, Paiva, Sandra, Queirós, Odília, and Soares-Silva, Isabel

Subjects

*CARBOXYLIC acids, *ORGANIC acids, *YEAST, *PROTEINS, *METABOLISM, *MAMMALS

Abstract

Carboxylic acid transporters form a heterogeneous group of proteins, presenting diverse mechanisms of action and regulation, and belonging to several different families. Multiple physiological and genetic studies in several organisms, from yeast to mammals, have allowed the identification of various genes coding for carboxylate transporters. Detailed understanding of the metabolism and transport of these nutrients has become more important than ever, both from a fundamental and from an applied point of view. Under a biotechnological perspective, the increasing economic value of these compounds has boosted this field of research considerably. Here we review the current knowledge on yeast carboxylate transporters, at the biochemical and molecular level, focusing also on recent biotechnological developments. [ABSTRACT FROM AUTHOR]

Published

2008

11. The conserved sequence NXX[S/T]HX[S/T]QDXXXT of the lactate/pyruvate:H+ symporter subfamily defines the function of the substrate translocation pathway.

Author

Soares-Silva, Isabel, Paiva, Sandra, Diallinas, George, and Casal, Margarida

Subjects

*CHROMOSOMAL translocation, *LACTATES, *PYRUVATES, *SACCHAROMYCES cerevisiae, *AMINO acids, *GENETIC mutation

Abstract

In Saccharomyces cerevisiae Jen1p is a lactate/proton symporter belonging to the lactate/pyruvate:H+ symporter subfamily (TC#2.A.1.12.2) of the Major Facilitator Superfamily. We investigated structure-function relationships of Jen1p using a rational mutational analysis based on the identification of conserved amino acid residues. In particular, we studied the conserved sequence 379 NXX[S/T]HX[S/T]QDXXXT 391. Substitution of amino acid residues N379, H383 or D387, even with very similar amino acids, resulted in a dramatic reduction of lactate and pyruvate uptake, but conserved measurable acetate transport. Acetate transport inhibition assays showed that these mutants conserve the ability to bind, but do not transport, lactate and pyruvate. More interestingly, the double mutation H383D/D387H, while behaving as a total loss-of-function allele for lactate and pyruvate uptake, can fully restore the kinetic parameters of Jen1p for acetate transport. Thus, residues N379, H383 or D387 affect both the transport capacity and the specificity of Jen1p. Substitutions of Q386 and T391 resulted in no or moderate changes in Jen1p transport capacities for lactate, pyruvate and acetate. On the other hand, Q386N reduces the binding affinities for all Jen1p substrates, while Q386A increases the affinity specifically for pyruvate. We also tested Jen1p specificity for a range of monocarboxylates. Several of the mutants studied showed altered inhibition constants for these acids. These results and 3D in silico modelling by homology threading suggest that the conserved motif analyzed is part of the substrate translocation pathway in the lactate/pyruvate:H+ symporter subfamily. [ABSTRACT FROM AUTHOR]

Published

2007

12. The disruption of JEN1 from Candida albicans impairs the transport of lactate.

Author

Soares-Silva, Isabel, Paiva, Sandra, Kätter, Peter, Entian, Karl-Dieter, and Casal, Margarida

Subjects

*CANDIDA albicans, *LACTATES, *GENES, *CARBOXYLIC acids, *CELL membranes, *ACETIC acid, *MESSENGER RNA, *MOLECULAR biology

Abstract

A lactate permease was biochemically identified in Candida albicans RM1000 presenting the following kinetic parameters at pH 5.0: K m 0.33±0.09 mM and V max 0.85±0.06 nmol s -1 mg dry wt -1 . Lactate uptake was competitively inhibited by pyruvic and propionic acids; acetic acid behaved as a non-competitive substrate. An open reading frame (ORF) homologous to Saccharomyces cerevisiae gene JEN1 was identified ( CaJEN1 ). Deletions of both CaJEN1 alleles of C. albicans (resulting strain CPK2) resulted in the loss of all measurable lactate permease activity. No CaJEN1 mRNA was detectable in glucose-grown cells neither activity for the lactate transporter. In a medium containing lactic acid, CaJEN1 mRNA was detected in the RM1000 strain, and no expression was found in cells of CPK2 strain. In a strain deleted in the CaCAT8 genes the expression of CaJEN1 was significantly reduced, suggesting the role of this gene as an activator for CaJEN1 expression. Both in C. albicans and in S. cerevisiae cells CaJEN1-GFP fusion was expressed and targeted to the plasma membrane. The native CaJEN1 was not functional in a S . c erevisiae jen1 Δ strain. Changing ser 217 -CTG codon (encoding leucine in S. cerevisiae) to a TCC codon restored the permease activity in S. cerevisiae , proving that the CaJEN1 gene codes for a monocarboxylate transporter. [ABSTRACT FROM AUTHOR]

Published

2004