Marco A. González-López scite author profile

Streptococcus pneumoniae, a human pathogen bacterium, can support its growth using haemoglobin (Hb) and haem as sole iron sources, but not when holo-transferrin or holo-lactoferrin is supplied. For this reason, it is easy to think that the principal iron sources for this pathogen inside humans are Hb and haem. Unfortunately, the mechanism has been poorly studied. The findings presented in this study are the first efforts that attempted to explain the mechanism involved in iron acquisition of this pathogen. This pathogen was capable of supporting its viability when iron sources such as Hb or haem were supplied. Membranes of S. pneumoniae were separated and their respective proteins were solubilized in order to be purified by haem-affinity chromatography. This strategy allowed us to purify seven membrane proteins. An experiment of competence with haem and iron showed two potential haem and Hb-binding proteins. Their Hb-binding function was confirmed by overlay assay using Hb and their respective identities were obtained by mass spectrometry. Then by amino acid alignment analysis, the motif involved in binding of Hb or haem was revealed. These results are the first findings that attempt to explain the mechanisms developed by S. pneumoniae to acquire iron from Hb or haem in the host, which could allow a better understanding of the biology of this bacterium.

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Helicobacter pylori secretes the chaperonin GroEL (HSP60), which binds iron

González-López

Velázquez-Guadarrama

Romero-Espejel

et al. 2013

FEBS Letters

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Helicobacter pylori is a bacterium that can use multiple iron sources. However, it is unknown whether this bacterium secretes molecules such as siderophores or haemophores to scavenge iron. Here, we report the first secreted iron-binding protein of H. pylori, which we purified by haem-affinity chromatography. Mass spectrometry analysis revealed its identity as chaperonin (HpGroEL). When we compared HpGroEL with EcGroEL from Escherichia coli, they were homologous, showing 60% similarity. Additionally, purified cytoplasmic HpGroEL could also bind iron. Perhaps H. pylori secretes HpGroEL to maintain the appropriate folding of extracellular proteins and to bind iron.

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The gene frpB2 of Helicobacter pylori encodes an hemoglobin-binding protein involved in iron acquisition

González-López

Olivares-Trejo

2009

Biometals

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Human hemoglobin (Hb) is a metalloprotein used by pathogens as a source of iron during invasive process. It can support the Helicobacter pylori growth and several proteins are induced during iron starvation. However, the identity of those proteins remains unknown. In this work, by in silico analysis we identified FrpB2 in H. pylori genome. This protein was annotated as an iron-regulated outer membrane protein. Multiple amino acid alignment showed the motifs necessary for Hb-binding. We demonstrate the ability of FrpB2 to bind Hb by overlay experiments. In addition, the overexpression of this gene allowed the cell growth in media without free iron but supplemented with Hb. All these results support the idea that frpB2 is a gene of H. pylori involved in iron acquisition when Hb is used as a sole iron source.

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Reducing the effective dose of cisplatin using gold nanoparticles as carriers

et al. 2020

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Background The increasing rate of cancer cases is alarming. In 2018, 9.6 million people died of the disease (WHO 2020). Current treatments, such as chemical therapy using cisplatin (CisPt) as a basis, cause considerable collateral damage to the patient (Ahmad 2017). CisPt acts as an alkylating agent with affinity to DNA, binds to the guanine and cytosine residues, and prevents the processes of replication and transcription of the genetic material, resulting in cell death by apoptosis (Ahmad 2017). However, cisplatin is unable to differentiate between normal and cancerous cells. Moreover, cancer cells can develop

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Streptococcus pneumoniae secretes a glyceraldehyde-3-phosphate dehydrogenase, which binds haemoglobin and haem

et al. 2014

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Streptococcus pneumoniae is a gram positive encapsulated bacterium responsible of septicaemia and upper respiratory infections in children. This pathogen requires iron to survive in the host, which it can obtain of haemoglobin (Hb) or haem. Only two Hb-binding membrane proteins have been identified up to now. However it is unknown whether this pathogen secretes proteins in order to scavenge iron from the Hb or haem. Therefore, in order to explore these possibilities, cellular growth of S. pneumoniae was tested with several alternative iron supplies. The bacterial growth was supported with iron, Hb and haem. Additionally, S. pneumoniae expressed and secreted a protein of 38 kDa which was purified and characterized as Hb and haem-binding protein. This protein was also identified by mass spectrometry as glyceraldehyde-3-phosphate dehydrogenase. Our overall results suggest that S. pneumoniae secretes a protein capable of binding two usefull iron sources for this bacterium (Hb and haem). This protein could be playing a dynamic role in the success of the invasive and infective processes of this pathogen.

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