Typical Families Today Essay Example for Free

Typical Families Today Essay To even a casual observer of American society over the past five decades, drastic changes in the fundamental makeup of the American family and the perceived image of the American family are readily apparent. Many factors have contributed to the evolution of the American family;   along with those changes, specific positive and negative impacts on the familial unit as a whole have been posited by sociologists and other observers and commentators. For many, the evolution of the American family signals a greater freedom for the individual; for many others, the evolution of the American family merely records a devolving of traditional cultural values and social support systems to modes of cultural disintegration.   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   Although it is difficult to determine with any reliability, the nature and true composition of a traditional American family, the surface-level societal image that stands as the most predominant is that of the nuclear family, which, while maintaining close ties among the immediate family members; mother, father, children differs from European (and other) cultures where family is extended much further into more distant relatives and tribal associations.   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚     At any rate, and despite the differences between the nuclear family and deeper historical models, the American family as nuclear stands as the single most definable image of family in the recent past. This model emphasized a patriarchal power-structure with the father as provider and protector and the mother as home-maker and care-giver. Just as many familial models from other cultures prioritize the family itself as the focal point of preservation and development, the American nuclear model places scant interest on individual growth or happiness. Family conflicts and interpersonal estrangement were regarded as obstacles to be overcome within the inter-dynamics of the family itself; individual happiness was desired or permitted in relation to its overall impact on the familys security and foundations.   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   Although the model of the nuclear family was likely never more than a functional abstraction for many people, for others, it did comprise a model by which to live and, indeed, sizable amounts of people did live their lives under the auspices of the nuclear family. In time, cultural evolution suggests that the restrictions on individual freedom, identity and ambition played a crucial role in the eventual breakdown of the nuclear family.   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   Among other key elements, The sexual revolution, womens liberation, relaxation of divorce laws, and greater mobility have been cited as forces which   are fracturing the traditional family structure, and these fractures are typically viewed as quite serious and with long-lasting consequences. In considering the sexual revolution it must be noted that this concept extends not only to unmarried couples with children, but to homosexual couples, childless couples, and those who are involved in some combination of the above. The opening of individual freedoms relative to sexual behavior has plunged the U.S into a rapidly changing family relationship landscape. Every assumption made about the family structure has been challenged, from the outer boundaries of single mothers raising out-of-wedlock children to gay couples having or adopting children to grandparents raising their grandchildren (Lebey, 2001, p. 20).   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   the increase in womens rights and legal recourses resulted in a rising number of divorces which contributed to the evolution of the American family. Single mothers and divorced couples rose in prominence among the statistical realities of how people actually lived rather than how Americans would like to imagine they lived. The evolution in traditional family structure started slow but maintained a steady pressure:   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   Fault lines in Americans family structure were widening throughout the last 40 years of   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   the 20th century. The cracks became evident in the mid 1970s when the divorce rate   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   doubled. According to a 1999 Rutgers University study, divorce has risen 30% since   Ã‚   1970; the marriage rate has fallen faster; and just 38% of Americans consider themselves   Ã‚  Ã‚  Ã‚   happy in their married state, a drop from 53% 25 years ago. Today, 51% of all marriages   Ã‚  Ã‚  Ã‚   end in divorce.   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   (Lebey, 2001, p. 20)   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   The basic shift is one from prioritizing the family, itself, as an end to be attained and the idea of the individual as the most important factor in developing life-relationships, career paths, sexual orientation, and lifestyle. Whereas by compulsion under the nuclear family, those family members who felt alienated or disregarded by their families were expected to deal with their alienation within the context of the family itself and certainly not by leaving the family, out-right, or out-right rejecting the familys primacy. If we grant Lebeys assertion that the four main societal changes [that have] occurred that have had an enormous impact on the traditional family structure. The sexual revolution, womens liberation movement, states relaxation of divorce laws, and mobility of American families then we should also take special note that her latter point: mobility of families and family members has probably played a larger role than any other single component in the actualization of the modern family.   (Lebey, 2001, p. 20)   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚     If our culture tends to focus on the individual, or, at most, on the nuclear family, downplaying the benefits of extended families, though their role is vital in shaping our lives it also protects and preserves individuals freedom of choice and freedom of lifestyle far above the sanctity or preservation of the family. Mobility is the most direct expression of individual freedom: The notion of moving on whenever problems arise has been a time-honored American concept. Too many people would rather cast aside some family member than iron out the situation and keep the relationship alive (Lebey, 2001, p. 20).   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   Mobility is not always a matter of choice but is often a matter of personal necessity driven on by employment conditions or other economic factors. Statistically, during the 10 years from 1989 to 1999, more than 5,000,000 families were relocated one or more times by their employers and this relocation is often driven by economic advancement and/or a safer place to raise children. From March, 1996, to March, 1997, 42,000,000 Americans, or 16% of the population, packed up and moved from where they were living to another location(Lebey, 2001, p. 20).   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   In addition to mobility, another aspect of lacing such a large emphasis on individual happiness and orientation is the idea that individual happiness is not only the paramount objective for personal decision making and interpersonal relationships, but that this idea of happiness should be also considered nearly inviolable. That is, the individual is socially conditioned to believe that any state that is less than happy is somehow abnormal, undesirable and should be remedied as soon as possible by whatever means: For at least 20 years, the pharmaceutical industry has learned how to cash in on the American obsession with feeling good by hyping mood drags to rewire the brain circuitry for happiness through the elimination of sadness and depression and this idea of constant happiness of course extends to ones marriages and familial relationships.   (Lebey, 2001, p. 20)   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   If one begins to regard individual happiness and individual ambition as the primary points of consideration in resolving inter-personal conflicts and especially inter-familial relationships, it is far more likely that breaks rather than repairations will be the result when issue of personal alienation or the restriction of self-expression and lifestyle intrude upon familial relationships. The overall decrease in an individuals willingness to work out tehir problems whatever they are and wherever they find themselves, along wiht a corresponding increase in the idea   of mobility, freedom, disposable jobs and relationship, brings about conditions which highly favor the radical evolution of the American family from its not-so-distant nuclear image.   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   The central question regarding the societal impact of the evolution of the American family on the societys well-being as a whole pivots on the idea of individual vs. collective rights. In other words, the evolution away form traditional family models toward those which encourage and encompass a much larger degree of individuality has resulted in a breakdown of the traditional family but also a breakthrough in individual freedoms and liberties. Whether or not the cult of the individual will provide a sufficient enough   substitution for nuclear family values in terms of providing for a healthy, growing, and just society remains to be seem. What is obvious is that traditional family models: one man, one women with fairly rigid gender roles and social mores is, indeed, a thing of the past.   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   The increasing number of non-married couples with children, of gay and lesbian couples with children, of single-parent families, and other non-traditional models is a highly visible indication of the social changes now occurring in America. No less visible or impacting is the rise of individuality and individual-orientation in American society which has both occasioned the breakdown of traditional family models and been enabled by the breakdown of traditional social mores and images of the typical American family.                   Reference Lebey, B. (2001, September). AMERICAN FAMILIES Are Drifting Apart. USA Today (Society   Ã‚  Ã‚  Ã‚  Ã‚  Ã‚  Ã‚   for the Advancement of Education), 130, 20.

The Perfect Gesture :: essays research papers

The Perfect Gesture. The perfect form football tackle, that is the perfect gesture. The person that made this gesture was Gary Kmiec. I witnessed this event for the first time, Labor Day, at the junior varsity football game against North Park College. The day was hot and humid, like a regular Chicago summer. The North Park Viking's field was hardly appealing to the eye. The field was one of those contraptions of a baseball/football field combination. It was the third quarter of a very intense game, the score was 8-6 we were winning. Both teams were relying on their defenses to stop the opposing offense and in our case to score. From what I have heard through the â€Å"grape vine† is that the offense of North Central isn't the greatest, but we have one of the best defenses. The stands, like every other junior varsity game, had only a handful of people in them. Most of the die-hard fans were either family or girlfriends. Unlike the North Park Vikings, who suited up over 60 players in their royal blue, our junior varsity team had suited up about 29 players total. Out of those 29 select few, only 13 were on the defensive side of the ball. North Park was on offense. The cardinal defense stood strong. It was second down and North Park needed five more yards to get the first down. I was not in the game at this time so I had an exceptional view. The Viking quarterback dropped back 2 steps then he handed the ball off to the half back. Kmiec, like he had always been taught, mirrored the half back shuffling parallel with him. Kmiec accelerated towards the ball carrier. Then it happened. The perfect gesture, the perfect tackle. This was it. Kmiec had reached top speed when he met the ball carrier. When they met, Kmiec placed his right shoulder pad in the gut of the running back, making him lose his breath. Kmiec then wrapped his hands around the back of the ball carrier and pinned him to the ground. His helmet hit the ball directly, causing the pigskin to fly free from the running backs grip. Our free safety, Bob Goins, was right behind Kmiec and recovered the fumble on the North Park 25 yard line. The North Central crowd cheered and the North Central sidelines were in an uproar.

Biol 130 First Midterm Notes

Unit 1 – Introduction to the Cell Robert Hooke – built the first microscope (30x magnification); viewed slices of cork called cellula (little rooms). Antoni Van Leeuwenhoek – worked with glass huge improvement in quality of lenses nearly 300x magnification became possible first to observe: * single-celled organisms â€Å"animalcules† * protists from pond water * bacteria from his mouth – â€Å"father of microbiology† * blood cells * banded pattern in muscle cells * sperm from †¦ 1830s – Compound microscope – improved magnification and resolution and allowed visualization of objects less than 1 ? . 1000-1500x magnification Beginning of Cell Theory Robert Brown (botanist) – noticed that every plant cell contained a round structure called it ‘kernel’-nucleus Matthias Schleiden (another botanist) – all plant tissues are composed of cells; embryonic plant always arose from a single cell Theodor Schwann (zoologist) – similar observations in animal cells; recognition of structural similarities btw plants and animals! * Cell Theory formulated by Schwann Cell Theory 1. all organisms consist of one or more cells 2. he cell is the basic unit of structure for all organisms 3. added 20 years later: all cells arise only from pre-existing cells fact (scientific) – an attempt to state our best current understanding, based on observations and experiments(valid only until revised or replaced) Steps in Scientific Method 1. make observations 2. use inductive reasoning to develop tentative explanation (hypothesis) 3. make predictions based on your hypothesis 4. make further observations or design and carry out controlled experiments to test your hypothesis 5. nterpret your results to see if they support your hypothesis Theory – a hypothesis that has been tested critically under many different conditions andby many different investigators . using a variety of different approa ches. By the time an explanation is regarded as a theory it is widely accepted by most scientists in the cell * the â€Å"solid ground† of science: evolution, germ theory, cell theory *If a theory is thoroughly tested and confirmed over many years by such large numbers of investigators that there is no doubt of its validity †¦ it may eventually be regarded as a law.Gravity, laws of thermodynamics, laws that govern behaviour of gases ‘Strands’ of Cell Biology 13 cytology 1600s Hooke looks at cork Leeuwenhoek looks at lots of things 1800s Brown notes nuclei bio-chemistry synthesis of urea in lab fermentation done by cells! glycolysis Krebs cycle every cell comes from a cell Schleiden & Schwann formulate cell theory electron microscopy stains & dyes genetics Mendel, pea plants DNA chromosomes chromosome theory 1930s DNA double helix DNA sequencing Dolly the sheep! nano-technology! genetic code Light Microscopy:Bright field – light passes through specimen , contrast is slow and specimen is hard to see Phase contrast – contrast is changed by changing light in microscope DIC – uses optical modifications to change contrast between cell and background – due to density differential Staining – stain used to visualize cell and components, only some stains can be used on living cells 14 bright field phase contrast DIC unstained (sperm cells) stained blood cells tissue – small intestine Fluorescent Microscopy – fluorescent dyes bind to protein or DNA to see where they are in cells – tracks movement Electron Microscopy(Scanning & Transmission):SEM – scan surface of specimen to form image by detecting electrons from outer surface. Good surface images TEM – forms image from electrons passing through specimen therefore fine details of internal organelles 16 SEM TEM Basic Properties of Cells: * are highly complex and organized * atoms molecules macromolecules (organelles ) enclosed in plasma membrane * use the same ‘genetic program’ Central Dogma * DNA RNA protein * are capable of reproducing themselves * must first replicate genetic material acquire and use energy (â€Å"bioenergetics†) and carry out a variety of chemical reactions (â€Å"cellular metabolism†) * have many processes that are highly conserved at the molecular level * membrane structure, genetic code, ATP synthesizing enzymes, actin filaments, eukaryotic flagella, †¦ * engage in many mechanical activities * transport of materials in/out, within * assembly and disassembly of structures * motility / movement * respond to environmental signals * move away or toward stimuli * respond to hormones, growth factors, etc * are capable of self-regulationâ€Å"homeostasis† most evident when control systems break down; defects in DNA replication, DNA repair, cell cycle control Two Classes of Cells – karyon = nucleus Prokaryotic Cells: lack of nucleus, NO CYTOSKELET ON(very small), membrane bound organelles. Mostly unicellular. Bacteria and Archaea. Single, circular strand of DNA(fewer proteins). Cell wall in addition to PM 1-10 uM in diameter. 2 types: 1. Eubacteria – all have cells walls except for mycoplasma(resistant to antibiotics that target cell wall synthesis). Mycoplasma(smallest) Cyanobacteria (largest and most complex). 2.Archaeabacteria – all have cell walls and are known as extermophiles, occupy broad range of habitats, halophiles=salty, acidophiles=acid, thermophiles= hot. Eukaryotic Cells: 10x larger than prokaryotic cells, membrane bound nucleus/organelles. More complex DNA due to histones/proteins. 4 groups: 1. Protists- very diverse group – mostly single cells; algae, water molds, slime molds, protozoa 2. Fungi – single cell(yeast) or multi-cellular(mushrooms) and have cell walls. Heterotrophs; depend on external source of organic compounds 3. Plant cells- multi-cellular and have cell walls. . Anima ls- multi-cellular, no cell walls and are heterotrophs Cytoplasm – everything between plasma membrane and nuclear membrane, includes all membrane-bound organelles (except nucleus) Cytosol – only fluid component Endomembrane system – internal membranes that are either in direct contact or connected via transfer of vesicles (sacs of membrane). including: nuclear envelope / membrane, endoplasmic reticulum (ER), Golgi apparatus, lysosomes, vacuoles Nucleus – stores genetic information Endomembrane System – creates intracellular compartments with different functions.Endoplasmic reticulum (ER; rough, smooth), Golgi apparatus, lysosomes. Mitochondria – generate energy to power the cell Chloroplasts – capture energy from sunlight, convert to carbohydrate Cytoskeleton – regulates cell shape, movements of materials within the cell, movement of the cell itself Flow of Traffic in EMS – Rough ER: synthesis of proteins for – ex port (secretion) – insertion into membranes – lysosomes Golgi apparatus: collection, packaging & distribution Lysosomes * cell ‘stomachs’ have enzymes that can digest †¦ * all 4 classes of biological macromolecules worn-out organelles (mitochondria replaced every 10 days) * material brought into cell by phagocytosis Phagocytosis – plasma membrane engulfs smaller molecule and then called phagosome. Lysosome takes it in and digests, small particles are releases into the cytoplasm. Autophagy – lysosome digests a damaged organelle, small particles are released into cytosol. mitochondria (all eukaryotic cells) and chloroplasts (plant cells): * contain DNA that encodes some (but not all) of their own proteins * have unusual double layers of membranesOrigin of Eukaryotic Cells: Endosymbiont Theory * once believed that eukaryotes evolved gradually, organelles becoming more and more complex * now accepted that early eukaryotes originated as preda tors * certain organelles (mitochondria, chloroplasts) evolved from smaller prokaryotes engulfed by larger cell * later chloroplasts and the ability to perform photosynthesis Symbiosis – Mutual Advantage advantage to host cell: * aerobic respiration (aerobic bacteria mitochondria) * photosynthesis (cyanobacteria chloroplasts) advantage to bacteria: * protected environment supply of carbon compounds from host cell’s other prey Evidence Supporting Endosymbiont Theory mitochondria and chloroplasts †¦ * are similar size to bacteria, reproduced by fission like bacteria * have double membranes, consistent with engulfing mechanism * have their own ribosomes, which resemble those of prokaryotes rather than eukaryotes in terms of size, composition and sensitivity to antibiotics * have their own genomes, which are organized like those of bacteria last but not least: * are genetically similar to proposed ‘parent’ bacteria rather than ukaryotic cells Cytoskeleton important in: * cell shape * cell motility * movement / position of organelles * movement of materials within cell * movement of chromosomes during mitosis Cytoplasm in a living cell is never static * cytoskeleton is constantly being taken apart and rebuilt * organelles and vesicles are racing back and forth * can cross the cell in ~ 1 second * unattached proteins moving randomly, but rapidly * can visit every corner of the cell within a few seconds * contents of cytosol are in constant thermal motionCommon to all cells: * selectively permeable plasma membrane * genetic code; mechanism of transcription and translation * ATP for the transfer of energy and metabolic pathways Model Organisms 45 Unit 2a – Intro to Cellular Chemistry Most Common Elements in Living Organisms: * C H O N – make up 96% – also P and S are common too * Exist as complex macromolecules and simpler forms like water and carbon dioxide nucleus – dense core in centre, consists of protons and neutrons electrons – continually orbit the nucleus # of protons – defining feature of an element = atomic number – # protons + # neutrons = mass of an atom = mass number – by default, an atom is ‘neutral’, with # protons = # electrons – electrons influence reactivity of an atom †¦ Atomic mass = atomic number + # of neutrons (electrons are neglected because mass is so small) Isotopes – same number of protons but different number of neutrons in the same element Anion – gain electron and are negatively charged Cation – lose electron and are positively chargedOutermost ‘valence’ shell influences an atom’s reactivity * electrons in outermost shell valence electrons * unpaired valance electrons determine the number of bonds an atom can make * atoms with filled valance shell = most stable, atoms that are closest to filling are most reactive * elements abundant in organisms have at least one u npaired valence electron Some Definitions: covalent bonds – two or more atoms share pairs of valence electrons * strong bonds of biological systems non-covalent bonds, including * ionic bonds * hydrogen bonds (H-bonds) * hydrophobic interactions olecule – group of atoms held together by energy in a stable association compound – molecule composed of two or more different types of atoms Types of Covalent Bonds * electrons shared ‘equally’ * non-polar covalent bond * can be single (like H2), double (O2) or even triple, depending on number of electrons shared * electrons not shared equally * polar covalent bond * one of the atoms has a stronger pull on the electrons than the other * pull on electrons = electronegativity * water is the most abundant molecule in biological organisms * human body is ~70% water water as a solvent can dissolve more types of molecules than other molecule known * the polarity of water is key to its role in biology hydrogen bon ding – electrical attraction between electronegative atom and partial positive of hydrogen hydrophobic – no affinity for water – â€Å"water fearing† hydrophilic – affinity for water – â€Å"water loving† Acid-base Reaction substance that gives up (donates) protons acid (increases [H+] in solution) substance that accepts protons base (decreases [H+] in solution) chemical reaction that involves transfer of protons acid-base reaction * most olecules act as either an acid or a base * water can be both (both gives up and accepts protons) weak acid: very few molecules dissociated (acetic acid, water) strong acid: readily gives up protons (hydrochloric acid) when pH = pKa species is 50% ionized Carbon is the most important element in biology carbon atoms give biomolecules their shape but other atoms attached to carbons determine their reactivity * critical H, N, O containing attachments called functional groups *learn orgo functional groups for this courseMacromolecules * large, organized molecules that are typically created by polymerization * biological macromolecules (biomolecules) provide the structure and carry out the activities of a cell 4 groups: * carbohydrates(polysaccharides) * lipids(fats) * proteins * nucleic acids * monomers of groups are different – chemical reactions used to make the chains are similar Overview of Macromolecules 3 Proteins – more functions than any other group of macromolecule * enzymes – catalysis; accelerate chemical reactions transport – through cell membranes, in circulation * support – cytoskeleton, fibres of cartilage, hair, nails * signalling / regulatory – hormones, membrane proteins, intracellular messengers * movement- of the cell itself – contractile proteins, flagella – within the cell – motor proteins * defense – antibodies, complement proteins Proteins are Polymers * amino acids are connected in linear polymers of a specific sequence * 20 genetically encoded amino acid monomers to pick from * string of amino acids (AAs) = peptide or polypeptide polypeptide folded and coiled into a specific conformation = protein * sometimes 2 or more peptide chains (subunits) combine to form mature, functional protein Amino Acid Structure AAs are ionized under physiological conditions ionization increases solubililty, facilitates interactions with each other and other solutes, increases reactivity (zwitterions) 7 non-ionized ionized R group unique to each AA oxygens tend to pull electrons away, making it easy to lose proton gains a proton Amino Acid Side Chains – R Groups: * nonpolar – hydrophobic R groups no charged or electronegative atoms to form H bonds * insoluble in water * R groups bury themselves with the peptide chain to ‘hide’ from water * polar side chains – soluble in water * uncharged – but partial charges can form H-bonds * charged – gr oups containing acids or bases – highly soluble in water AA are linked together by covalent peptide bonds: carbon from carboxyl group is linked to N terminus of amino group. R groups and central C’s do not participate in the bond. Condensation Reaction – making the chain Hydrolysis – breaking the chain Polypeptide chain: side chains extend from peptide-bonded backbone * chain is flexible – can rotate at single bonds on either side of peptide bonds * so side chains are not all projecting to one side! * chains can be from 2-3 to thousands of AAs in length * backbone is directional, convention is to number AA ‘residues’ starting at N terminus this is the primary sequence Sickle Cell Anemia – disease in which red blood cells are abnormally shaped. Caused by single point mutation which results in substitution of single amino acid in one chain of hemoglobin protein Protein Structure:Primary Structure – unique sequence of amino acids Secondary Structure – Folding into elements of structure, hydrogen bonding between amino acids(R groups not involved). 2 shapes: alpha helix and beta pleated sheet(parallel and antiparallel). * learn more Tertiary Structure- interactions of elements of secondary structure forming a global fold, folded into these unique shapes by ionic bonds (electrostatic),hydrogen bonds, disulphide bridges, hydrophobic interaction, van der waals – dipole-dipole(all non-covalent except for S-S). Order of amino acids determines final shape.Maintain globular shape even if very weak. Quaternary Structure – more than one polypeptide chain put together to form the final functional protein, linked by covalent and non-covalent interactions. Protein Domain – segment of polypeptide that forms a compact, stable and independently folding structure. Often the building blocks for larger, more complex proteins. Disulfide bonds * covalent stabilization of protein structure found i n secreted proteins (destined for a more hostile extracellular environment) * formed in ER (oxidizing environment)Once folded, do proteins ever unfold? changes in physical or chemical conditions (pH, salt concentration, temperature) disruption of H-bonds, ionic bonds, disulfide bridges, etc that maintain the protein’s shape protein ‘denatures’ or unfolds Possible to renature Do proteins ever fold incorrectly? any mutation that leads to a missing or incorrect amino acid can lead to incorrectly folded protein WHY 32 Possible outcomes: mutation – leads to incorrectly folded protein * protein never functions properly loss of function protein folds properly at first but unfolds under certain conditions eventually loss of function * protein misfolds AND is deposited in insoluble aggregates within cell * loss of function and disruption of other aspects of cell activity * many human diseases now known to be associated with misfolded proteins . Alzheimers, cystic f ibrosis, type II diabetes, retinitis pigmentosa, Parkinsons, Creutzfeldt-Jakob, some cancers *read about catalysts and enzymes in Janelle’s notes, page 8-9 Nucleic Acids: Information Polymers * deoxy ribo nucleic acid (DNA) sequence of subunits in DNA polymer directs RNA synthesis * ribo nucleic acid (RNA) * RNA directs ordering of AAs in a peptide chain * information stored as DNA sequences enables living organisms to pass on hereditary information * also allows each cell to pass on hereditary information to the next generation of cells Monomers of Nucleic Acids: Deoxyribo nucleotides – phosphate + deoxyribose + nitrogenous base(A,C, G, or T) Ribo nucleotides – phosphate + ribose + base (A,C,G, or U) Nucleic acids are linear (unbranched) polymers of nucleotides * each nucleotide consists of three parts: * a nitrogenous base a (5-carbon) pentose sugar * a phosphate group Purines = A&GPyramidines= C,T and U * Ribose + base = nucleoside * Ribose + base + phosphate = nucleotide Functions of Nucleotides * monomeric units of RNA and DNA * important signal molecules within cells * cyclic adenosine monophosphate (cAMP) * important agents in energy transfer reactions * cleave off phosphate group to release stored energy * act as coenzymes – organic non-protein molecules required for enzyme function * usually adenine-containing nucleotides combined with B vitamins 8 condensation reaction 5’ end – beginning of chain. Chains always built 5’ 3’.Look at above example phosphate group is 5’ 3’ end – where new bases can be added Polymerization rxn’s are endergonic: * making phosphodiester bonds requires energy * energy comes from addition of 2 phosphate groups. * Activated nucleotides = nucleotide triphophates The most famous phosphorylated nucleotide †¦ adenosine triphosphate = ATP 11 adenine 4’ 5’ 5 6 1 2 3 9 4 8 7 1’ 3’ 2’ O P CH2 O O O– P O O O– P O –O O– OH OH O NH2 N N N N ribose adenine + ribose (= adenosine) Secondary Structure of DNA: two strands of DNA align in ‘antiparallel’ arrangement with bases facing inwards. H-bonds form between bases. P P P P P P P P C C G G AA T T P O O O O O O O O O O O C G OH P Note: 3 H-bonds between C and G, 2 between A and T. Only space in the sugar phosphate backbone is for Pyramidine and Purine to bond together. Features of DNA Double Helix * stabilized by H-bonds between complementary bases and hydrophobic interactions between bases * entire molecule water-soluble because charged phosphates backbone face outward * major and minor grooves are significant in regulation of gene transcription Higher Order DNA Structure: DNA molecules can adopt higher order structure – Allows for compact packaging and strict regulation of gene expression RNA vs DNA like DNA: sugar-phosphate backbone covalently linked by phosphodiester bonds * 4 different bases unl ike DNA: * uracil (U) instead of thymine (T) * pairing is A-U, C-G * sugar is ribose instead of deoxyribose * hydroxyl group makes ribose much more reactive * RNA is much less stable than DNA Secondary Structure of RNA: like DNA: * H-bonds form between complementary base pairs unlike DNA: * most of the time, this base-pairing is between bases on the same strand * leads to formation of ‘stem and loop’ structures with single-stranded regions and double-stranded antiparallel regions * H-bonding is spontaneous, stabilizes the molecule final molecule is single-stranded * Complex folds can result in some RNA having catalytic activity Carbohydrates * Group of molecules that contain carbon, hydrogen and oxygen in a 1:2:1 ratio: (CH2O)n Only monomers are in this ratio, oligomers you lose water * Monomer=monosaccharide * Dimer=disaccharide * Trimer=trisaccharide/oligosaccharide Types: 1. Monosaccharides – simple sugars 2. Oligosaccharides – small chains (oligo=few) * Attached to proteins – glycoproteins * Attached to lipids – glycolipids 3. Polysaccharides – very long sugar chains Typical Structural Features of Sugar Monomers: carbonyl group (either ketone or aldehyde) * lots of -OH groups * vary in length of carbon skeleton (C3, C5, C6, †¦) – triose, pentose, hexose * isomeric forms (glucose, fructose, galactose) * identical chemical groups arranged differently * monosaccharides often form rings in solution Isomers – same atoms, different arrangements structural isomer – identical groups but bonded to different carbons stereo (optical) isomer – identical groups bonded to same carbons but in different orientations sixteen different hexose structures possible, all with formula C6H12O6 C OH C OH OH H C OH H HO C H C O H C OH H H C OH H C OH H C OH H HO C H H C OH H structural isomer stereo- isomer H C C O HO C H H C OH H C OH H HO C H H C OH H fructose glucose galactose *arrangement of hydrox yl groups make a big difference in biological function Disaccharide – 2 sugar monomer: * glucose + fructose = sucrose(table sugar) * glucose + lactose = lactose * glucose + glucose = maltose Formation of disaccharides by condensation reactions. monomers are linked when C1 of one monosaccharide binds to a C on another – often C4 geometry of bond different depending on hether OH group of C1 is in ? or ? position which C of other sugar is involved in linkage 7 C1, ? C4 ?-glucose ?-glucose maltose, ? -1,4 glycosidic bond ?-galactose ?-glucose lactose, ? -1,4 glycosidic bond (glucose has flipped over) C1, ? C4 Polymerization to build Polysaccharides starch both are storage forms for energy starch – plants; glycogen – animals both consist of ? -glucose monomers linked by ? -1,4 bonds both coil into a helix (due to geometry of linkages) starch is mixture of unbranched amylose and branched amylopectin glycogen is highly branched lycogen Structural Polysaccharide in Plants: Cellulose 9 polymer of ? -glucose, joined by ? -1,4 linkages each glucose is flipped relative to adjacent ones allows for H-bonding between adjacent strands extremely stable most abundant organic molecule on earth parallel strands joined by H-bonds Structural Polysaccharide in Animals: Chitin a component of cell walls of fungi, exoskeletons of arthropods (insects, crustaceans), radulas of molluscs, beaks of cephalopods second most abundant organic molecule on earth like cellulose, joined by ? 1,4 linkages but rather than glucose, monomer is N-acetylglucosamine like cellulose, also strengthened by H-bonding btw strands 10 Structural Polysaccharide in Bacteria: Peptidoglycan component of bacterial cell walls the most complex CHO so far! two different alternating monomers linked by ? -1,4 bonds chain of amino acids attached to one of the sugars – peptide bonds instead of H-bonds (stronger) Significance of how monosaccharides are linked: * ? -1-4 linkages of starch and glycogen readily hydrolyzed * ? 1-4 linkages in structural polysaccharides very resistant to enzymatic degradation For example: enzymes that digest cellulose (cellulase) produced only by certain classes of bacteria, fungi and protozoa Difference between glycosidic bonds from peptide and phosphodiester bonds: in common: * condensation reactions different: * peptide and phosphodiester bonds always occur at the same position within their monomers * each sugar monomer has several hydroxyl groups, and geometry of glycosidic bonds is highly variable Functions of Carbohydrates: Structural: * cellulose, chitin and peptidoglycanCell-cell recognition: * membrane proteins covalently bonded to oligosaccharides Energy Storage * ? -1,4 –linkages of starch and glycogen are readily hydrolyzed to release stored energy Lipids * group of carbon-containing compounds that are largely non-polar / hydrophobic * significant proportion of a given lipid molecule is hydrocarbon * the only macromolecul e that is not a polymer major groups of lipids in cells: * fats / oils – energy storage * sterols * cholesterol – membrane component * steroids – hormones * * Phospholipids * major component of biological membranesFats (Triacylglycerols, Triglycerides) * form that fat is stores in apidose tissie * glycerol with 3 fatty acids attached * the link between glycerol and fatty acid = ester bond: condenstation rxn (liberates water) * hydrophobic * fatty acid(carboxylic acid with long hydrocarbon tail) Saturated Fatty Acid – have maximum number of hydrogen atoms on each atom; straight and flexible because of only single bonds Unsaturated Fatty Acid – contain at least 1 double bond. The double bond is rigid and creates a kink in the chain. The rest of the chain however is free to rotate about C-C bonds.Cis – H on the same side of double bond; don’t solidify easily Trans – H on the opposite side of the double bond. Hydrogenation – making a fat saturated/more solid at room temperature to improve shelf life therefore less healthy. Sterols – group of steroids based on cholesterol(important component of cell membrane) Phospholipids : * 1 glycerol, 2 fatty acids, 1 phosphate group(polar head group) * Amphipathic = hydrophilic and hydrophilic regions – their most important feature with respect to biology Micelles – sphere with hydrophobic tails ‘hiding’ in centre . Can only occur with relatively short tails Lipid Bilayer:Universal Structure for all Biological Membranes composition varies with: type of organism (prokaryote vs animal vs plant vs †¦) type of cell within organism (muscle, liver, sperm, egg, †¦) type of membrane within cell (plasma membrane, Golgi, ER) inner versus outer layer different patches or ‘domains’ within a particular membrane Fig 11-4 two closely apposed sheets of lipids, studded with proteins lipids serve as permeability barrier protei ns perform most of the functions carbohydrates (sugars) attached to protein and lipids in a non-random manner *all membrane lipids are amphipathic Lipid bilayers form spontaneously: hydrophobic molecules would exclude water, clustering together to minimize energy cost of organizing water molecules * form large droplets or surface film * amphipathic molecules are subject to conflicting forces * solved by formation of bilayer * energetically most favourable stable, spontaneous * lipid bilayers are †¦ * closed – no free edges * self-sealing * important feature for cell fusion, budding, locomotion Fluid Mosaic Model * The plasma membrane is described to be fluid because of its hydrophobic integral components such as lipids and membrane proteins that move laterally or sideways throughout the membrane.That means the membrane is not solid, but more like a ‘fluid'. * phospholipids are constantly moving spinning in place; travelling laterally within ‘leaflet’ * phospholipids are occasionally ‘flipped’ to the opposite leaflet during membrane synthesis but they rarely ‘flop’ back * even proteins cruise slowly through the membrane! Membrane fluidity – how easily lipid molecules move within a membrane leaflet Alignment of phospholipid tails * tightly packed tails membrane more viscous, less fluid * freely moving tails higher fluidity What aspects of phospholipid composition influence this? length of fatty acids * from 14-24 carbons, 18-20 carbons most common * degree of saturation of fatty acids # double bonds * typically one saturated fatty acid and one with one or more double bonds Cholesterol: * under physiological conditions, cholesterol makes membrane stiffer – less fluid * cholesterol can make up to 50% of plasma membrane lipid in some animal cells Regulation of Membrane Fluidity: – fluid state must be maintained for normal cell function strategies for maintaining membrane fluidity: * chang e composition of membranes * alter phospholipids desaturate fatty acids (to deal with cold) eg cold water vs warm water fish * change length of FA chains (yeast, bacteria) * adjust amounts of cholesterol (animals) these mechanisms have been demonstrated in: * pond fish dealing with dramatic day / night temp differences * cold-resistant plants * extremophile bacteria living in hot springs * winter wheat preparing for autumn ^ polyunsaturated FAs * sperm reduce their cholesterol just before fertilization †¦ Functions of Lipids: * storage of chemical energy * signal molecules * vitamins * wax coating on leaves * biological membranes

America s Choice 1960 Presidential Campaign - 904 Words

History`s choice-1960 Presidential campaign What respectable person would think of the best choice for president? There are plenty of classical case of presidential campaigns in past years. In 1960, the Soviet Union and the United States were in the Cold War. Nevertheless, civil rights and the fight against apartheid and other issues cause a lot of trouble. According to these historical background, there are two politicos began to compete for president: John F. Kennedy, a young and dynamic Massachusetts senator; Nixon, an experienced members of congress. Compared with Kennedy and Nixon before the presidential campaign, Kennedy not only the lack of rich diplomatic experience, but also in a disadvantaged situation of his identity of Catholics. However, Kennedy won the presidential campaign by his unique advantage. There are several differences and similarities between Kennedy and Nixon that cause the final result of the presidential campaign. Religion entered the campaign in 1960 as 19 28 and it s importance can not be underestimated. Kennedy and Nixon have a different religion. Many citizens voted for their religion rather than their politics. In the article, author shows us that some protestant democrats supported Nixon for religious reasons. As a catholic, Kennedy didn`t in a dominant position. However, Kennedy had disposed of the religious issue. On September 12, Kennedy agreed to appear before the Ministerial Association of Houston, Texas, to present his viewsShow MoreRelatedThe Life of John Fitzgerald Kennedy Essay948 Words   |  4 Pageshad, in doing this, the greatest impact on religion than any modern president. John F. Kennedy was only the second Catholic to run for president in the history of the United State (Denison). According to Jim Denison, â€Å"from the beginning of the campaign, his (Kennedy’s) Catholic commitment was a hotly-debated subject. 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