Cytochrome Proteins

<body topmargin=0 leftmargin=0 marginheight=0 marginwidth=0> <table cellpadding=0 cellspacing=0 border=0><tr> <td valign="top" height=30 BGCOLOR="#006699" TEXT="#080000"> <div> <FONT SIZE="2" COLOR="#FFFBF0" FACE="Arial" ><B>The Natural Science Institute</B></FONT> <FONT SIZE="1" COLOR="#000000" FACE="Arial" >      </FONT>  <A HREF="index.htm" TARGET="_top" TITLE="The Natural Science Institute"><U>Home Page</U></A>                                            Our Electron Transport - Cytochromes                                                 <B> </B></div> </td> </tr><tr> <td valign="top" height=450 BGCOLOR="#FFFFFF" TEXT="#080000"> <div> <TABLE BORDER="1" CELLPADDING="0" CELLSPACING="0" WIDTH="758" BORDERCOLORLIGHT="#BBBBBB" BORDERCOLORDARK="#BBBBBB" FRAME="BOX" RULES="ALL" ALIGN="BOTTOM" HSPACE="0" VSPACE="0" > <tR> <tD VALIGN=TOP HEIGHT= 2801 ><NOBR><div> <B>New </B></div> <div> NSI - Research Index<FONT SIZE="1" COLOR="#FFFFCC" FACE="Arial" >..</FONT></div> <div>   1.<A 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><B>1</B></FONT></div> <div> Cyto-chromes are the colored sections of protein,</div> <div> which give the cytoplasm,in our cells,their unique colors,</div> <div> This is why, the word starts with,<I>C</I><I>yto</I>- which tells us, </div> <div> that they are found, in the <I>cyto-plasm</I> of our cells and</div> <div> finishes with <I>-chrome</I>, from Chromatic,meaning very<I> colorful</I>.</div> <div> <IMG SRC="4f6539a0.gif" border=0 width="339" height="154" ALT="Red Blood Cell Making Bone Cells" ALIGN="BOTTOM" HSPACE="0" VSPACE="0"></div> <div> It took many years, for scientists,to discover the uses, </div> <div> of these dark red and dark brown lengths of protein, because, </div> <div> they tend to cause our cells, to be too dark, to see through.</div> <div> This is why, research scientists,have always, </div> <div> had to wash them out of the cells,they wanted to study, </div> <div> before they began,to study those cells,in order for them, </div> <div> to see,into the cells with their light microscopes.</div> <div> Now with,microscopes that use pions and electrons,</div> <div> to sense the components of our cell organelles,</div> <div> they can discern the more finite activitys of our cells.</div> <div> Which is why,several teams of U.K.scientists,</div> <div> began to save the cytoplasm of various cells,</div> <div> in several different types of wax-like solutions </div> <div> And then studied them,with pion and electron microscopes, </div> <div> which are not affected by the colors of chemical samples.</div> <div> They soon learned, there are several types of cytochromes.</div> <div> There are small peptide cytochrome proteins,</div> <div> that bring,the trace minerals,that we eat, </div> <div> to the different types of cell tissue,such as exist in, </div> <div> our liver, lungs, pancreas, speen, nerves and muscles</div> <div> And, there are those,poly-peptide cytochrome proteins, </div> <div> that help our cell Mitochondria,restore damaged cell components,</div> <div> by bringing,each of the cell mitochondria,in every one of our cells, </div> <div> oxygen, hydroxyls and methyls for the tips of the alkane esters. .</div> <div> They also found, that at the ends of those cytochrome peptides,</div> <div> there are those,long,multi-cyclic, tubular steroid alkaloids,</div> <div> which they called, the cytochrome protein's "c<I>yto-dynes</I>"</div> <div> That carry several metal atoms,inside their long tubular sections,</div> <div> which are similar to,the phenylene sections of aromatic molecules, </div> <div> This gives those cytochrome peptides,their ability to attract,</div> <div> the groups of metal atoms,which are in the trace minerals,</div> <div> that they carry,to damaged cell tissue,which then will be used </div> <div> by our mitochondria to restore,any damaged cell components, </div> <div> This they found is,how our bodys,use blood cytochrome protein,</div> <div> to place the iron, boron, copper and zinc,into the protective scabs, </div> <div> which our body creates,over our open wounds.</div> <div> <IMG SRC="4fb329a0.gif" border=0 width="306" height="154" ALT="NAD and Folate Using Lymph Cells" ALIGN="BOTTOM" HSPACE="0" VSPACE="0"></div> <div> When scientists, in European laboratorys, heard of their success, </div> <div> they also, began to save,discarded blood cytochromes </div> <div> and started to study their attributes.  Soon, they discovered, </div> <div> That we have penta-peptide, blood cell cytochrome proteins,</div> <div> which have either, a long, multi-cyclic NAD phenyl aldehyde or,</div> <div> A long multi-cyclic FAD phenyl aldehyde,at one end or both ends </div> <div> They discovered in our thorax,in specific peptides,we also use </div> <div> multi'cyclic,Folic Acid aldehyde at one end and at the other end, </div> <div> a metal atoms transporting,multi-cyclic copper NAD aldehyde, </div> <div> to restore wounds or heal cells damaged by pesticides.</div> <bR> <div> Those Euro Labs scientists,then discovered,there are,</div> <div> more than 3 types of restorative cytochrome hemo-proteins.</div> <div> Their studys revealed,there are,2 cytochrome proteins,</div> <div> with multicyclic Iron-NAD aldehyde enzymes, </div> <div> that are used in our liver and others </div> <div> with multi-cyclic Boron NAD aldehyde,cytodyne enzymes</div> <div> that we use in our spongy bone cells,bone periosteum and tendons.</div> <div> The Czech team found cytochrome protein, </div> <div> with multicyclic Iron-FAD aldehyde,in our pancreas, </div> <div> and multi-cyclic Zinc-FAD aldehyde, in our intestinal vein walls.</div> <div> Then Romanian scientists found cytochrome proteins, </div> <div> with long, multi-cyclic,Copper-FAD aldehyde,enzymes,</div> <div> in our liver sinuses,duct walls,veins,gallbladder walls </div> <div> and our transverse colon,tenia coli muscle cells.</div> <div> This last discovery,promises to provide,a method,</div> <div> for creating protein supplements,that can help to restore, </div> <div> patients transverse colons after restorative abdominal surgery.</div> <div> They also discovered,that tubular cyclic Folic Acid aldehyde,</div> <div> is used in almost all of our small cytochrome protein peptides, </div> <div> with Tyrosine,the star azines Glycine and Methionine,</div> <div> and the metal atoms carrying NAD and FAD cytodynes,</div> <div> which carry from 4 to12 atoms of those healing metals,</div> <div> inside their long tubular,phenyl-aldehyde side sections.</div> <div> The long multi-cyclic tubular,acetyl aldehyde,Methyl Ester Folic Acid,</div> <div> known also as FH4 tetra hydro folic acid,was found to be the initiator,</div> <div> transferase for the majority of those cytochrome,protein peptides,</div> <div> in the arterys of our lungs,chest and upper back </div> <div> They also found a 3 peptide cytochrome with Tyrosine, </div> <div> as its initiator transferase, which brought hydroxyls, </div> <div> to the isles of lipid storage,in the golgi apparatus,</div> <div> in our cartilage cells and in our bone cells </div> <div> And another polypeptide,cytochrome protein,with asparagine,</div> <div> as its initiator transferase, that helped to bring oxygen and hydrogen,</div> <div> to the cell vacuoles and small fosforosome organelles,in our bone cells.</div> <div> Hans Krebs,did not describe these cytochromes,since,he washed out,</div> <div> the cytochrome proteins,because, he was taught,by his histology teacher, </div> <div> "They were undesireable dark pigments"which make it difficult to see into,</div> <div>   the cells and mitochondria of the small laboratory animals, </div> <div> Therefore,his observations describe,the process of catabolism,</div> <div> in cells which have been deprived of their cytochromes</div> <div> that provide the cells oxygen and hydrogen and minerals,</div> <div> Cells revert to,catabolism,if they are deprived of food, as during periods,</div> <div> of fasting or starvation,when they are deprived of adequate polypeptides,</div> <div> lipids,pure mineralized water and disease free, fresh air.</div> <div> This is why, the Krebs Theory and his concepts about electron transport </div> <div> are not now accepted by the medical and sceintific professions.</div> <bR> <div> With the discovery of the structure and uses of the NAD and FAD cytodynes</div> <div> by Dr.Manly, it is now possible,to design medicines,which,can be grouped </div> <div> with methyl ester folic aldehyde,Glycine,NAD and needed star azines,into, </div> <div> Transferase polypeptides that can carry the medicines into infected cells,</div> <div> because,infected cells normally are deficient in cytodynes and TH4.</div> <div> At present doctors find a 2/3 of prescribed medicines do not go into, </div> <div> infected cells,but instead,are encysted in the walls of patients arterioles,</div> <div> or enclosed in cysts and fatty lipomas in a patients kidneys.  </div> <bR> <div> Once IUPAC and the AMA learn from Dr.Manly how to synthesize,</div> <div> the NAD.FAD and TH4 cytodyne cytochromes,it should be possible,</div> <div> to cure all major infections in 24 hours,instead of 24 days..</div> <bR> <div>                                                                                                <A HREF="cytochromes_m.htm" TITLE="Cytochrome Proteins "><U>Back to Top</U></A></div> <bR> <bR> <bR> <bR> <bR> <bR> </NOBR></tD> </tR> </TABLE></div> <bR> <bR> <bR> <bR> <bR> <bR> <bR> <bR> <bR> </td> </tr></table></body>