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PW000195

Pw000195 View Pathway
disease

Zellweger Syndrome

Homo sapiens
Zellweger syndrome, also known as cerebrohepatorenal syndrome, is an autosomal recessive peroxisome biogenesis disorder that is part of the family of Zellweger spectrum disorders. It is caused by a defect in one of 12 or more of the PEX genes (PEX1, 2, 3, 5, 6, 10, 12, 13, 14, 16, 19 and 26) that produce proteins called peroxins. Peroxins are used in the formation of peroxisomes, and can be involved in recognition of proteins targeted for the peroxisome, as well as their transport into the peroxisome. Peroxisomes typically break down both very long chain and branched fatty acids, but if they aren't present, these fatty acids build up in the blood and body, harming organs such as the brain and liver. Additionally, due to the fact that some processes, such as plasmalogen biosynthesis, occur in or using peroxisomes, and can lead to deficiencies in plasmalogens. These are important in brain and lung function, leading to other symptoms. Zellweger syndrome is characterized by an increase in levels of very long chain fatty acids in the blood plasma, as well as more visible physical symptoms, such as an abnormally large or small head at birth, characteristic facial features and poor muscle tone, which can lead to an inability of infants to feed. Other symptoms include an enlarged liver, skeletal abnormalities and low CNS function. Infants very rarely live longer than one year, and the only treatment is for symptoms the patient is experiencing, not for the syndrome itself.

PW121749

Pw121749 View Pathway
disease

Zellweger Syndrome

Mus musculus
Zellweger syndrome, also known as cerebrohepatorenal syndrome, is an autosomal recessive peroxisome biogenesis disorder that is part of the family of Zellweger spectrum disorders. It is caused by a defect in one of 12 or more of the PEX genes (PEX1, 2, 3, 5, 6, 10, 12, 13, 14, 16, 19 and 26) that produce proteins called peroxins. Peroxins are used in the formation of peroxisomes, and can be involved in recognition of proteins targeted for the peroxisome, as well as their transport into the peroxisome. Peroxisomes typically break down both very long chain and branched fatty acids, but if they aren't present, these fatty acids build up in the blood and body, harming organs such as the brain and liver. Additionally, due to the fact that some processes, such as plasmalogen biosynthesis, occur in or using peroxisomes, and can lead to deficiencies in plasmalogens. These are important in brain and lung function, leading to other symptoms. Zellweger syndrome is characterized by an increase in levels of very long chain fatty acids in the blood plasma, as well as more visible physical symptoms, such as an abnormally large or small head at birth, characteristic facial features and poor muscle tone, which can lead to an inability of infants to feed. Other symptoms include an enlarged liver, skeletal abnormalities and low CNS function. Infants very rarely live longer than one year, and the only treatment is for symptoms the patient is experiencing, not for the syndrome itself.

PW128043

Pw128043 View Pathway
drug action

Ziconotide Analgesia Action Pathway

Homo sapiens
Ziconotide, also known as SNX-111, is an N-type calcium channel antagonist used to manage patients with severe chronic pain who cannot tolerate, or who have not responded adequately to other treatments such as intrathecal morphine and systemic analgesics. Ziconotide is a neurotoxic peptide derived from the cone snail Conus magus comprising 25 amino acids with three disulphide bonds. It is used to manage severe chronic pain through the inhibition of N-type calcium channels involved in nociceptive signalling.Ziconotide was granted FDA approval on December 28, 2004 under the brand name Prialt. To date, ziconotide is the only calcium channel blocking peptide approved for use by the FDA. Nociceptive pain signalling is a complex processing pathway involving peripheral nociceptors, primary afferent nerve fibres, and downstream CNS neurons located in the spinal cord such as the dorsal root ganglion. Voltage-gated calcium channels (VGCCs) are important regulatory components of neural signalling, including type-N voltage-gated calcium channels. N-type channel activate lightly myelinated Aδ- and C-fibres, which mediate the release of neurotransmitters substance P, calcitonin gene-related peptide (CGRP), and glutamate. This causes downstream nociceptive neuronal activity and pain perception. Substance P and CGRP both also induce inflammation, further exasperating chronic pain. Ziconotide inhibits Voltage-dependent N-type calcium channels in presynaptic neurons. This prevents calcium from entering the neuron which prevents neurotransmitter release from the dorsal root ganglion as well as other nociceptive neurons. Therefore substance P, CGRP, and glutamate are not released into the synapse and cannot activate the substance P receptors, CGRP receptors, or the N-Methyl-D-aspartic acid receptors on the post-synaptic neuron. This causes hyperpolarization, with a down-stream effect of hyperalgesia, a prevention of pain signalling.

PW145700

Pw145700 View Pathway
drug action

Ziconotide Drug Metabolism Action Pathway

Homo sapiens

PW127942

Pw127942 View Pathway
drug action

Ziconotide NMDA and Substance P Receptor Pain Inhibition Action Pathway

Homo sapiens
Ziconotide, also known as SNX-111, is an N-type calcium channel antagonist used to manage patients with severe chronic pain who cannot tolerate, or who have not responded adequately to other treatments such as intrathecal morphine and systemic analgesics. Ziconotide is a neurotoxic peptide derived from the cone snail Conus magus comprising 25 amino acids with three disulphide bonds. It is used to manage severe chronic pain through the inhibition of N-type calcium channels involved in nociceptive signalling.Ziconotide was granted FDA approval on December 28, 2004 under the brand name Prialt. To date, ziconotide is the only calcium channel blocking peptide approved for use by the FDA. Nociceptive pain signalling is a complex processing pathway involving peripheral nociceptors, primary afferent nerve fibres, and downstream CNS neurons located in the spinal cord such as the dorsal root ganglion. Voltage-gated calcium channels (VGCCs) are important regulatory components of neural signalling, including type-N voltage-gated calcium channels. N-type channel activate lightly myelinated Aδ- and C-fibres, which mediate the release of neurotransmitters substance P, calcitonin gene-related peptide (CGRP), and glutamate. This causes downstream nociceptive neuronal activity and pain perception. Substance P and CGRP both also induce inflammation, further exasperating chronic pain. Ziconotide inhibits Voltage-dependent N-type calcium channels in presynaptic neurons. This prevents calcium from entering the neuron which prevents neurotransmitter release from the dorsal root ganglion as well as other nociceptive neurons. Therefore substance P, CGRP, and glutamate are not released into the synapse and cannot activate the substance P receptors, CGRP receptors, or the N-Methyl-D-aspartic acid receptors on the post-synaptic neuron. This causes hyperpolarization, with a down-stream effect of hyperalgesia, a prevention of pain signalling.

PW123945

Pw123945 View Pathway
drug action

Zidovudine Action Action Pathway

Homo sapiens
Zidovudine is a medication used to prevent and to treat HIV/AIDS. It is part of the an antiretroviral and belongs to the NRTI class of drugs, also known as nucleoside reverse transcriptase inhibitors and its generic name is azidothymidine. Zidovudine is generally taken orally, which begins this pathway. After being ingested, Zidovudine is transported into the cell using 6 transporters, namely SLC28A1, SLC28A3, SLC22A6, SLC22A7, SLC22A8, and SLC22A11. After entering the cell, Zidovudine is converted by TK1 to create zidovudine monophosphate. Zidovudine monophosphate is then turned into zidovudine diphosphate through the enzyme DTYMK. Zidovudine diphosphate undergoes a final transformation into zidovudine triphosphate, before being able to perform its intended function and inhibiting HIV RT. Zidovudine also undergoes two other branches of reactions upon entering the cell, the first being catalyzation into 5’-glucuronyl zidovudine, and subsequently being converted by an unknown protein into 3’amino-3’-deoxy-5’-glcopyranuronosylthymidine, which is then eliminated. The second branch of reactions that zidovudine undergoes is its conversion to 3’-amino-3’-deoxythymidine, through the various proteins CYP2C9, CYP2A6, CYP2E1, CYP3A4, and POR, which may or may not be cytotoxic in the cell.

PW000724

Pw000724 View Pathway
drug action

Zidovudine Action Pathway

Homo sapiens
The discovery of AIDS prompted the search for agents that block the HIV replication process. Zidovudine (AZT) is a nucleoside analogue of thymidine, and was shown to reduce considerably the mortality of patients with AIDS. Zidovudine is toxic to the hemtopoietic system, causing anemia and neutropenia. It is clear, however, that disease progression can occur during continued administration of zidovudine. Moreover, zidovudine is not effective in treating Kaposi sarcoma, a common complication of HIV infection. Zidovudine therapy is also associated with a high incidence of toxicity, primarily bone marrow suppression, that requires dosage reduction or discontinuation of the therapy.

PW126451

Pw126451 View Pathway
drug action

Zidovudine Anti-Viral Action Pathway

Homo sapiens
Zidovudine is a nucleoside reverse transcriptase inhibitor (NRTI) used in combination with other antiretroviral agents for the treatment of human immunodeficiency virus (HIV) infections. When HIV infects a cell, the virus first binds and fuses with the cell, releasing its nucleocapsid containing its RNA and reverse transcriptase into the cytosol of the cell. The reverse transcriptase converts the viral RNA into viral DNA in the cytosol. The viral DNA goes to the nucleus through the nuclear pore complex where it undergoes the process of transcription. The new viral RNA formed from transcription is transported back to the cytosol through the nuclear pore complex and translation occurs to produce viral proteins. These viral proteins are assembled and new HIV viruses bud from the cell. Zidovudine enters the cell via solute carrier family 22 member 6 and is converted into zidovudine monophosphate by thymidine kinase. Thymidylate kinase then converts zidovudine monophosphate into zidovudine diphosphate. Zidovudine diphosphate is metabolized to zidovudine triphosphate via nucleoside diphosphate kinase A. Zidovudine triphosphate is an analog of deoxyguanosine triphosphate (dGTP). Zidovudine diphosphate inhibits the activity of HIV-1 reverse transcriptase by competing with its substrate, dGTP and by incorporation into viral DNA. Zidovudine triphosphate lacks the 3'-OH group which is needed to form the 5′ to 3′ phosphodiester linkage essential for DNA chain elongation, therefore, once Zidovudine triphosphate gets incorporated into DNA, this causes DNA chain termination, preventing the growth of viral DNA. Less viral proteins are therefore produced, and there is a reduction in new viruses being formed. Zidovudine has a high frequency of side effects that limits its use. Side effects of taking zidovudine may include nausea, vomiting, diarrhea, headaches, myalgia, insomnia, bone marrow suppression, peripheral myopathy, elevated liver enzyme, lactic acidosis and hepatotoxicity.

PW144617

Pw144617 View Pathway
drug action

Zidovudine Drug Metabolism Action Pathway

Homo sapiens

PW127122

Pw127122 View Pathway
metabolic

Zidovudine Metabolism

Homo sapiens