Lab

Sabina M Maté's Lab


About the lab

Our main goal is the study of lipid-lipid and lipid-protein interactions which are key factors affecting the organization, structure and function of biological membranes. For the development of this line, classical biochemical and biophysical methodologies are used as well as more recent development methodologies, such as Atomic Force Microscopy (AFM) and Force Spectroscopy (FS), Surface Plasmon Resonance (SPR), Langmuir Balance -Brewster's angle microscopy (BAM) and infrared absorption-reflection spectroscopy with polarization modulation (PM-IRRAS), among others. Finally, we develop and provide relevant biophysical and analytical methods for lipid and membrane research. We are eager to share our experience through collaborations with the scientific community!

Featured research (36)

Sphingolipids-enriched rafts domains are proposed to occur in plasma membranes and to mediate important cellular functions. Notwithstanding, the asymmetric transbilayer distribution of phospholipids that exists in the membrane confers the two leaflets different potentials to form lateral domains as next to no sphingolipids are present in the inner leaflet. How the physical properties of one leaflet can influence the properties of the other and its importance on signal transduction across the membrane are questions still unresolved. In this work, we combined AFM imaging and Force spectroscopy measurements to assess domain formation and to study the nanomechanical properties of asymmetric supported lipid bilayers (SLBs) mimicking membrane rafts. Asymmetric SLBs were formed by incorporating N-palmitoyl-sphingomyelin (16:0SM) into the outer leaflet of preformed 1,2-Dioleoyl-sn-glycero-3-phosphocholine (DOPC)/Cholesterol SLBs through methyl-β-cyclodextrin–mediated lipid exchange. Lipid domains were detected after incorporation of 16:0SM though their phase state varied from gel to liquid ordered (Lo) phase if the procedure was performed at 24 or 37 °C, respectively. When comparing symmetric and asymmetric Lo domains, differences in size and morphology were observed, with asymmetric domains being smaller and more interconnected. Both types of Lo domains showed similar mechanical stability in terms of rupture forces and Young's moduli. Notably, force curves in asymmetric domains presented two rupture events that could be attributed to the sequential rupture of a liquid disordered (Ld) and a Lo phase. Interleaflet coupling in asymmetric Lo domains could also be inferred from those measurements. The experimental approach outlined here would significantly enhance the applicability of membrane models.
Oxytocin plays a pivotal role in the regulation of human parturition, however its role and modulation in the placenta is not fully understood. Non-labour cesarean section placentas were cultured with the endocannabinoid anandamide. We observed an increase in placental oxytocin receptor expression and oxytocin release. We postulate anandamide as a relevant modulator of oxytocin system in the placenta at term.
The Membrane Attack Complex-Perforin (MACPF) family is ubiquitously found in all kingdoms. They have diverse cellular roles but MACPF but pore-forming toxic function are very rare in animals. Here we present the structure of PmPV2, a MACPF toxin from the poisonous apple snail eggs, that can affect the digestive and nervous systems of potential predators. We report the three-dimensional structure of PmPV2, at 15 Å resolution determined by negative stain electron microscopy (NS-EM) and its solution structure by small angle X-ray scattering (SAXS). We found that PV2s differ from nearly all MACPFs in two respects: it is a dimer in solution and protomers combine two immune proteins into an AB toxin. MACPF chain is linked by a single disulfide bond to a tachylectin chain, and two heterodimers are arranged head-to-tail by non-covalent forces in the native protein. MACPF domain is fused with a putative new Ct-accessory domain exclusive to invertebrates. Tachylectin is a six-bladed β-propeller, similar to animal tectonins. We experimentally validated the predicted functions of both subunits and demonstrated for the first time that PV2s are true pore-forming toxins. The tachylectin B delivery subunit would bind to target membranes, and then its MACPF A toxic subunit disrupt lipid bilayers forming large pores altering the plasma membrane conductance. These results indicate that PV2s toxicity evolved by linking two immune proteins where their combined preexisting functions give rise to a new toxic entity with a novel role in defense against predation. This structure is an unparalleled example of protein exaptation.
Alpha hemolysin (HlyA) is the major virulence factor of uropathogenic Escherichia coli (UPEC) strains. Once in circulation, a low concentration of the toxin induces an increase in intracellular calcium that activates calpains-which proteolyse cytoskeleton proteins-and also favors the exposure of phosphatidylserine (PS) in the outer leaflet of erythrocyte membranes. All these events are considered part of eryptosis, as well as the delivery of microvesicles (MVs). Within this context, we studied the delivery of MVs by erythrocytes treated with sublytic concentrations of HlyA and demonstrated that HlyA-treated erythrocytes secrete MVs of diameter approximately 200 nm containing HlyA and PS by a mechanism involving an increment of intracellular calcium concentration and purinergic receptor activation. Despite the presence of toxin in their membrane, HlyA-MVs are not hemolytically active and do not induce ATP release in untreated erythrocytes, thus suggesting that the delivery of HlyA-MVs might act as a protective mechanism on the part of erythrocytes that removes the toxin from the membrane to prevent the spread of infection. Although erythrocytes have been found to eliminate denatured hemoglobin and several membrane proteins by shedding MVs, the present work has revealed for the first time that an exogenous protein, such as a toxin, is eliminated by this process. This finding sheds light on the mechanism of action of the toxin and serves to further elucidate the consequences of UPEC infection in patients exhibiting HlyA-related diseases.

Lab head

Sabina M Maté
Department
  • Facultad de Ciencias Médicas
About Sabina M Maté
  • Sabina M Maté currently works at the Facultad de Ciencias Médicas, National University of La Plata. Sabina does research in Physiology, Molecular Biology and Cell Biology. Their current project is 'Effect of Lipid-lipid and lipid-protein interactions on membrane structure'.

Members (1)

Romina F. Vázquez
  • National University of La Plata
Leobardo Serrano Carreon
Leobardo Serrano Carreon
  • Not confirmed yet
Sathishkumar Munusamy
Sathishkumar Munusamy
  • Not confirmed yet
Laura Bakás
Laura Bakás
  • Not confirmed yet
Romina F. Vázquez
Romina F. Vázquez
  • Not confirmed yet
Pablo Pelinski
Pablo Pelinski
  • Not confirmed yet
Hugo Barbero
Hugo Barbero
  • Not confirmed yet