Identification of early biomarkers in saliva in genetically engineered mouse model C(3)1-TAg of breast cancer.

Breast cancer is one of leading causes of death worldwide in the female population. Deaths from breast cancer could be reduced significantly through earlier and more efficient detection of the disease. Saliva, an oral fluid that contains an abundance of protein biomarkers, has been recognized as a promising diagnostic biofluid that is easy to isolate through non-invasive techniques. Assays on saliva can be performed rapidly and are cost-effective. Therefore, our work aimed to identify salivary biomarkers present in the initial stages of breast cancer, where cell alterations are not yet detectable by histopathological analysis. Using state-of-the-art techniques, we employed a transgenic mouse model of mammary cancer to identify molecular changes in precancerous stage breast cancer through protein analysis in saliva. Through corroborative molecular approaches, we established that proteins related to metabolic changes, inflammatory process and cell matrix degradation are detected in saliva at the onset of tumor development. Our work demonstrated that salivary protein profiles can be used to identify cellular changes associated with precancerous stage breast cancer through non-invasive means even prior to biopsy-evident disease.

Proteomic analysis reveals rattlesnake venom modulation of proteins associated with cardiac tissue damage in mouse hearts.

Snake envenomation is a common but neglected disease that affects millions of people around the world annually. Among venomous snake species in Brazil, the tropical rattlesnake (Crotalus durissus terrificus) accounts for the highest number of fatal envenomations and is responsible for the second highest number of bites. Snake venoms are complex secretions which, upon injection, trigger diverse physiological effects that can cause significant injury or death. The components of C. d. terrificus venom exhibit neurotoxic, myotoxic, hemotoxic, nephrotoxic, and cardiotoxic properties which present clinically as alteration of central nervous system function, motor paralysis, seizures, eyelid ptosis, ophthalmoplesia, blurred vision, coagulation disorders, rhabdomyolysis, myoglobinuria, and cardiorespiratory arrest. In this study, we focused on proteomic characterization of the cardiotoxic effects of C. d. terrificus venom in mouse models. We injected venom at half the lethal dose (LD50) into the gastrocnemius muscle. Mouse hearts were removed at set time points after venom injection (1 h, 6 h, 12 h, or 24 h) and subjected to trypsin digestion prior to high-resolution mass spectrometry. We analyzed the proteomic profiles of >1300 proteins and observed that several proteins showed noteworthy changes in their quantitative profiles, likely reflecting the toxic activity of venom components. Among the affected proteins were several associated with cellular deregulation and tissue damage. Changes in heart protein abundance offer insights into how they may work synergistically upon envenomation. SIGNIFICANCE: Venom of the tropical rattlesnake (Crotalus durissus terririficus) is known to be neurotoxic, myotoxic, nephrotoxic and cardiotoxic. Although there are several studies describing the biochemical effects of this venom, no work has yet described its proteomic effects in the cardiac tissue of mice. In this work, we describe the changes in several mouse cardiac proteins upon venom treatment. Our data shed new light on the clinical outcome of the envenomation by C. d. terrificus, as well as candidate proteins that could be investigated in efforts to improve current treatment approaches or in the development of novel therapeutic interventions in order to reduce mortality and morbidity resulting from envenomation.

Identification of early biomarkers in saliva in genetically engineered mouse model C(3)1-TAg of breast cancer

Breast cancer is one of leading causes of death worldwide in the female population. Deaths from breast cancer could be reduced significantly through earlier and more efficient detection of the disease. Saliva, an oral fluid that contains an abundance of protein biomarkers, has been recognized as a promising diagnostic biofluid that is easy to isolate through non-invasive techniques. Assays on saliva can be performed rapidly and are cost-effective. Therefore, our work aimed to identify salivary biomarkers present in the initial stages of breast cancer, where cell alterations are not yet detectable by histopathological analysis. Using state-of-the-art techniques, we employed a transgenic mouse model of mammary cancer to identify molecular changes in precancerous stage breast cancer through protein analysis in saliva. Through corroborative molecular approaches, we established that proteins related to metabolic changes, inflammatory process and cell matrix degradation are detected in saliva at the onset of tumor development. Our work demonstrated that salivary protein profiles can be used to identify cellular changes associated with precancerous stage breast cancer through non-invasive means even prior to biopsy-evident disease.

Proteomic analysis reveals rattlesnake venom modulation of proteins associated with cardiac tissue damage in mouse hearts

Snake envenomation is a common but neglected disease that affects millions of people around the world annually. Among venomous snake species in Brazil, the tropical rattlesnake (Crotalus durissus terrificus) accounts for the highest number of fatal envenomations and is responsible for the second highest number of bites. Snake venoms are complex secretions which, upon injection, trigger diverse physiological effects that can cause significant injury or death. The components of C. d. terrificus venom exhibit neurotoxic, myotoxic, hemotoxic, nephrotoxic, and cardiotoxic properties which present clinically as alteration of central nervous system function, motor paralysis, seizures, eyelid ptosis, ophthalmoplesia, blurred vision, coagulation disorders, rhabdomyolysis, myoglobinuria, and cardiorespiratory arrest. In this study, we focused on proteomic characterization of the cardiotoxic effects of C. d. terrificus venom in mouse models. We injected venom at half the lethal dose (LD50) into the gastrocnemius muscle. Mouse hearts were removed at set time points after venom injection (1 h, 6 h, 12 h, or 24 h) and subjected to trypsin digestion prior to high-resolution mass spectrometry. We analyzed the proteomic profiles of >1300 proteins and observed that several proteins showed noteworthy changes in their quantitative profiles, likely reflecting the toxic activity of venom components. Among the affected proteins were several associated with cellular deregulation and tissue damage. Changes in heart protein abundance offer insights into how they may work synergistically upon envenomation. Significance Venom of the tropical rattlesnake (Crotalus durissus terririficus) is known to be neurotoxic, myotoxic, nephrotoxic and cardiotoxic. Although there are several studies describing the biochemical effects of this venom, no work has yet described its proteomic effects in the cardiac tissue of mice. In this work, we describe the changes in several mouse cardiac proteins upon venom treatment. Our data shed new light on the clinical outcome of the envenomation by C. d. terrificus, as well as candidate proteins that could be investigated in efforts to improve current treatment approaches or in the development of novel therapeutic interventions in order to reduce mortality and morbidity resulting from envenomation.

Bothrops Jararaca Snake Venom Modulates Key Cancer-Related Proteins in Breast Tumor Cell Lines.

Cancer is characterized by the development of abnormal cells that divide in an uncontrolled way and may spread into other tissues where they may infiltrate and destroy normal body tissue. Several previous reports have described biochemical anti-tumorigenic properties of crude snake venom or its components, including their capability of inhibiting cell proliferation and promoting cell death. However, to the best of our knowledge, there is no work describing cancer cell proteomic changes following treatment with snake venoms. In this work we describe the quantitative changes in proteomics of MCF7 and MDA-MB-231 breast tumor cell lines following treatment with Bothrops jararaca snake venom, as well as the functional implications of the proteomic changes. Cell lines were treated with sub-toxic doses at either 0.63 µg/mL (low) or 2.5 µg/mL (high) of B. jararaca venom for 24 h, conditions that cause no cell death per se. Proteomics analysis was conducted on a nano-scale liquid chromatography coupled on-line with mass spectrometry (nLC-MS/MS). More than 1000 proteins were identified and evaluated from each cell line treated with either the low or high dose of the snake venom. Protein profiling upon venom treatment showed differential expression of several proteins related to cancer cell metabolism, immune response, and inflammation. Among the identified proteins we highlight histone H3, SNX3, HEL-S-156an, MTCH2, RPS, MCC2, IGF2BP1, and GSTM3. These data suggest that sub-toxic doses of B. jararaca venom have potential to modulate cancer-development related protein targets in cancer cells. This work illustrates a novel biochemical strategy to identify therapeutic targets against cancer cell growth and survival.

Bothrops Jararaca snake venom modulates key cancer-related proteins in breast tumor cell lines

Cancer is characterized by the development of abnormal cells that divide in an uncontrolled way and may spread into other tissues where they may infiltrate and destroy normal body tissue. Several previous reports have described biochemical anti-tumorigenic properties of crude snake venom or its components, including their capability of inhibiting cell proliferation and promoting cell death. However, to the best of our knowledge, there is no work describing cancer cell proteomic changes following treatment with snake venoms. In this work we describe the quantitative changes in proteomics of MCF7 and MDA-MB-231 breast tumor cell lines following treatment with Bothrops jararaca snake venom, as well as the functional implications of the proteomic changes. Cell lines were treated with sub-toxic doses at either 0.63 μg/mL (low) or 2.5 μg/mL (high) of B. jararaca venom for 24 h, conditions that cause no cell death per se. Proteomics analysis was conducted on a nano-scale liquid chromatography coupled on-line with mass spectrometry (nLC-MS/MS). More than 1000 proteins were identified and evaluated from each cell line treated with either the low or high dose of the snake venom. Protein profiling upon venom treatment showed differential expression of several proteins related to cancer cell metabolism, immune response, and inflammation. Among the identified proteins we highlight histone H3, SNX3, HEL-S-156an, MTCH2, RPS, MCC2, IGF2BP1, and GSTM3. These data suggest that sub-toxic doses of B. jararaca venom have potential to modulate cancer-development related protein targets in cancer cells. This work illustrates a novel biochemical strategy to identify therapeutic targets against cancer cell growth and survival.

The impact of rattlesnake venom on mice cerebellum proteomics points to synaptic inhibition and tissue damage.

Snake envenomation is responsible for more than 130,000 deaths worldwide. In Brazil, the Crotalus rattlesnake is responsible for the second largest number of accidental snake bites in the country. Although there are many descriptions of the clinical and biochemical effects of Crotalus envenoming, there are few works describing the molecular events in the central nervous system of an organism due to envenomation. In this study, we analyzed the proteomic effect of Crotalus durissus terrificus snake venom on mice cerebellums. To monitor the envenomation over time, changes in the protein abundance were evaluated at 1 h, 6 h, 12 h and 24 h after venom injection by mass spectrometry. The analysis of the variation of over 4600 identified proteins over time showed a reduction in components of inhibitory synapse signaling, oxidative stress, and maintenance of neuronal cells, which paralleled increasing tissue damage and apoptosis factors. These analyses revealed the potential protein targets of the C. d. terrificus venom on the murine cerebellum, showing new aspects of the snake envenomation effect. These data may contribute to new therapeutic approaches (i.e., approaches directed at protein targets affected by the envenomation) on the treatment of envenomation by the neurotoxic C. d. terrificus snake venom. SIGNIFICANCE: Snakebites are a neglected global health problem that affects mostly rural and tropical areas of developing countries. It is estimated that over 5.4 million people are bitten by snakes each year, from which 2.7 million people are bitten by venomous snakes, resulting in disabilities such as amputations and in some cases leading to death. The C. d. terrificus snake is the most lethal snake in Brazil. Studying the molecular changes upon envenomation in a specific tissue may lead to a better understanding of the envenomation process by C. d. terrificus snakebites.

The impact of rattlesnake venom on mice cerebellum proteomics points to synaptic inhibition and tissue damage

Snake envenomation is responsible for more than 130,000 deaths worldwide. In Brazil, the Crotalus rattlesnake is responsible for the second largest number of accidental snake bites in the country. Although there are many descriptions of the clinical and biochemical effects of Crotalus envenoming, there are few works describing the molecular events in the central nervous system of an organism due to envenomation. In this study, we analyzed the proteomic effect of Crotalus durissus terrificus snake venom on mice cerebellums. To monitor the envenomation over time, changes in the protein abundance were evaluated at 1 h, 6 h, 12 h and 24 h after venom injection by mass spectrometry. The analysis of the variation of over 4600 identified proteins over time showed a reduction in components of inhibitory synapse signaling, oxidative stress, and maintenance of neuronal cells, which paralleled increasing tissue damage and apoptosis factors. These analyses revealed the potential protein targets of the C. d. terrificus venom on the murine cerebellum, showing new aspects of the snake envenomation effect. These data may contribute to new therapeutic approaches (i.e., approaches directed at protein targets affected by the envenomation) on the treatment of envenomation by the neurotoxic C. d. terrificus snake venom. Significance Snakebites are a neglected global health problem that affects mostly rural and tropical areas of developing countries. It is estimated that over 5.4 million people are bitten by snakes each year, from which 2.7 million people are bitten by venomous snakes, resulting in disabilities such as amputations and in some cases leading to death. The C. d. terrificus snake is the most lethal snake in Brazil. Studying the molecular changes upon envenomation in a specific tissue may lead to a better understanding of the envenomation process by C. d. terrificus snakebites.

The impact of rattlesnake venom on mice cerebellum proteomics points to synaptic inhibition and tissue damage

Snake envenomation is responsible for more than 130,000 deaths worldwide. In Brazil, the Crotalus rattlesnake is responsible for the second largest number of accidental snake bites in the country. Although there are many descriptions of the clinical and biochemical effects of Crotalus envenoming, there are few works describing the molecular events in the central nervous system of an organism due to envenomation. In this study, we analyzed the proteomic effect of Crotalus durissus terrificus snake venom on mice cerebellums. To monitor the envenomation over time, changes in the protein abundance were evaluated at 1 h, 6 h, 12 h and 24 h after venom injection by mass spectrometry. The analysis of the variation of over 4600 identified proteins over time showed a reduction in components of inhibitory synapse signaling, oxidative stress, and maintenance of neuronal cells, which paralleled increasing tissue damage and apoptosis factors. These analyses revealed the potential protein targets of the C. d. terrificus venom on the murine cerebellum, showing new aspects of the snake envenomation effect. These data may contribute to new therapeutic approaches (i.e., approaches directed at protein targets affected by the envenomation) on the treatment of envenomation by the neurotoxic C. d. terrificus snake venom. Significance Snakebites are a neglected global health problem that affects mostly rural and tropical areas of developing countries. It is estimated that over 5.4 million people are bitten by snakes each year, from which 2.7 million people are bitten by venomous snakes, resulting in disabilities such as amputations and in some cases leading to death. The C. d. terrificus snake is the most lethal snake in Brazil. Studying the molecular changes upon envenomation in a specific tissue may lead to a better understanding of the envenomation process by C. d. terrificus snakebites.

In vitro cleavage of bioactive peptides by peptidases from Bothrops jararaca venom and its neutralization by bothropic antivenom produced by Butantan Institute: Major contribution of serine peptidases.

In Brazil, envenomation by Bothrops pitvipers is responsible for over 73% of snakebites, and their venom is a rich source of proteolytic enzymes. Most studies have demonstrated that Bothrops jararaca venom acts on macromolecular substrates, causing an imbalance in the victim's hemostatic system. In contrast, fewer studies have examined the proteolytic activity on small molecules such as peptides. In this study, we used a set of bioactive peptides (insulin B chain, Met-enkephalin, Leu-enkephalin, neuropeptide Y, peptide YY, pancreatic polypeptide, substance P and somatostatin) to identify new peptide substrates for the metallopeptidases and serine peptidases from the B. jararaca venom. The majority of these peptides were substrates for the venom, but neuropeptide Y and pancreatic polypeptide presented higher hydrolyses rates. Although most of the peptides were simultaneously substrates for both classes of proteases, serine peptidases were the most active. Substance P was an exclusive substrate for metallopeptidases, while somatostatin was a selective substrate for serine peptidases. The neutralizing efficacy of the bothropic antivenom produced by the Butantan Institute was also assessed and found to totally prevent substance P hydrolysis, whereas somatostatin cleavage was not inhibited. Thus, the antivenom effectively inhibited metallopeptidase activity, but did not neutralize some of the serine peptidases. These results indicate that, in addition to cleaving proteins, the proteolytic enzymes from this venom also hydrolyze bioactive peptides, and this peptidase activity could effectively contribute to some of the many dire manifestations of envenomation.

In vitro cleavage of bioactive peptides by peptidases from Bothrops jararaca venom and its neutralization by bothropic antivenom produced by Butantan Institute: major contribution of serine peptidases

In Brazil, envenomation by Bothrops pitvipers is responsible for over 73% of snakebites, and their venom is a rich source of proteolytic enzymes. Most studies have demonstrated that Bothrops jararaca venom acts on macromolecular substrates, causing an imbalance in the victim's hemostatic system. In contrast, fewer studies have examined the proteolytic activity on small molecules such as peptides. In this study, we used a set of bioactive peptides (insulin B chain, Met-enkephalin, Leu-enkephalin, neuropeptide Y, peptide YY, pancreatic polypeptide, substance P and somatostatin) to identify new peptide substrates for the metallopeptidases and serine peptidases from the B. jararaca venom. The majority of these peptides were substrates for the venom, but neuropeptide Y and pancreatic polypeptide presented higher hydrolyses rates. Although most of the peptides were simultaneously substrates for both classes of proteases, serine peptidases were the most active. Substance P was an exclusive substrate for metallopeptidases, while somatostatin was a selective substrate for serine peptidases. The neutralizing efficacy of the bothropic antivenom produced by the Butantan Institute was also assessed and found to totally prevent substance P hydrolysis, whereas somatostatin cleavage was not inhibited. Thus, the antivenom effectively inhibited metallopeptidase activity, but did not neutralize some of the serine peptidases. These results indicate that, in addition to cleaving proteins, the proteolytic enzymes from this venom also hydrolyze bioactive peptides, and this peptidase activity could effectively contribute to some of the many dire manifestations of envenomation.

Large protein as a potential target for use in rabies diagnostics

Rabies is a zoonotic viral disease that remains a serious threat to public health worldwide. The rabies lyssavirus (RABV) genome encodes five structural proteins, multifunctional and significant for pathogenicity. The large protein (L) presents well-conserved genomic regions, which may be a good alternative to generate informative datasets for development of new methods for rabies diagnosis. This paper describes the development of a technique for the identification of L protein in several RABV strains from different hosts, demonstrating that MS-based proteomics is a potential method for antigen identification and a good alternative for rabies diagnosis.