2014 Group Project 2

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2014 Student Projects
2014 Student Projects: Group 1 | Group 2 | Group 3 | Group 4 | Group 5 | Group 6 | Group 7 | Group 8
The Group assessment for 2014 will be an online project on Fetal Development of a specific System.

This page is an undergraduate science embryology student and may contain inaccuracies in either description or acknowledgements.

Renal

--Mark Hill (talk) 15:11, 26 August 2014 (EST) No subheadings yet and I even had to add your project title! Get moving.

--Mark Hill (talk) 16:00, 6 September 2014 (EST) OK some sub-headings and a few refs. No content yet expelling the feral component or how the references you have selected relate to the topic.

Introduction

The renal system's main function is the production, storage and elimination of urine, and to maintain the balance of chemicals and water of the body. Kidneys are the primary organ of the renal system, and consist of smaller units known as nephrons - which filter the blood to remove urea and other wastes, and reabsorb or excrete excess water according to the needs of the body as directed by hormones released by the pituitary glands. Nephrons are made up of glomeruli to filter the blood, tubules to reabsorb any solutes or fluids, and more tubule networks to carry the urine to the bladder and outside the body. Small amounts of urine is released from the kidneys every 1 ~ 15 seconds into the ureter, which carry the urine to the bladder.[1] The bladder is a hollow organ which has the ability to change its epithelium according to how full the bladder is of urine. "The bladder's walls relax and expand to store urine, and contract and flatten to empty urine through the urethra. The typical healthy adult bladder can store up to two cups of urine for two to five hours.”[2] Two sphincter muscles are present at the base of the bladder, and two more at the end of the urethra (internal & external) to voluntarily control the excretion of urine.

Development of these components begin during the embryonic phase, and continue to develop and mature throughout the fetal stages. During the fetal stages, some abnormalities may form. During the embryonic period and fetal periods, the mother's placenta work to remove wastes from the fetus.

Abnormalities may arise during the embryonic and fetal stages of development of the renal system, such as Hereditary renal adysplasia, or polycystic kidney disease. Hereditary renal adysplasia is an inherited condition, where there is malformations in organs derived of the embryonic mesoderm.[3] Polycystic kidney disease is a fairly common genetic disorder in which fluid-filled cysts displace normal renal tubules.[4]

Historic findings

Developmental Timeline

Week 3 – nephrogenesis begins, pronephri form

Week ~4 - embryonic development of ureter begins from the ureteric bud

Week 5 – metanephros forms

Week 8 – mature kidney is formed

Week ~10 - Kidneys begin to produce urine

Week 11-12 - degeneration of the mesonephri

Week 36 – nephrogenesis is complete, however can occur as early as week 32

Postnatal – maturation of neonatal glomerular filtration

Current research models

Animals are good models to use when researching the development of the renal system as there are fewer ethical issues surrounding animals compared with humans and their generation time is much shorter so mutations can be identified much faster.

One recent research paper buy Al-Odat et al. used mice in order to determine the impact of maternal cigarette smoke exposure on the development of the renal system, in particular kidneys. It was proposed that smoke exposure would lead to a change in the expression of growth and transcription factors which would lead to kidney disease later on in life. The experiment found that some fibroblast growth factors were up-regulated whilst others were down-regulated and this led to delayed nephron development and fewer nephrons present at birth. The study showed by using an animal model that cigarette smoke exposure during pregnancy and lactation period leads to underdeveloped renal system which can result in chronic kidney disorders in adulthood. [5]

Pringle et al. carried out a study and used lambs as their model in order to look at the affects and possible cures for Lower Urinary Tract Obstruction. Lower Urinary Tract Obstruction affects many newborns and is one of the most common causes of renal failure in young children; therefore it is important to find a way to prevent the damages to the renal system caused by the obstruction. A bladder obstruction was created in the lambs; this was done by ligating the urachus, 3 or 4 weeks after the obstruction was created shunts were put into the lambs so that the urine was able to bypass the obstruction; two different shunts were created, one had a valve and the other did not. The results found that the shunt without a valve resulted in the lamb foetus having a small, shrunken and thick-walled had poor function whereas the lambs with a valve shunt had a much better bladder function which was similar to the bladder without the shunt. This shows that the cycle of filling and emptying the bladder with urine during foetal development is very important for the formation of the bladder.[6]

Kidney

Early Development

File:Development of Kidney.jpg
The development of the kidney from epithelial origin to fully formed

The kidneys first develop in the embryo by a process called nephrogenesis, in which self-renewing mesenchymal renal stem cells produce nephrons, the main functional unit, and form a simple embryonic kidney called the pronephros [7]. This process of nephron formation is stimulated by the signaling between the ureteric buds and these stem cells, named progenitor cells and located at the tips of the ureteric buds, causing nephrons to develop and the ureteric buds to branch [8].

When sufficient development has occurred during week 3 of gestation, two pronephri are produced and nephrotomes, a series of tubules, begin to fuse together with the pronepheric duct. As the pronephri continue to develop, they elongate and induce the nearby mesoderm to form mesonephri, and the pronepheric duct to become the mesonephric (Woffian) duct. Towards the bottom of this duct, close to where it connects to the cloaca, is the ureteric bud connected by the ureter. Surrounding this bud is a mass of metanephric mesoderm (blastema), the two of which react together to form the metanephros which goes on to form the mature kidney. The cells of the ureteric bud differentiate to form the major and minor calyces as well as the collecting tubules, while the cells of the metanephrogenic blastema develop into the renal tubules and glomeruli. This process begins from as early as week 3 and continues until week 8 of gestation. The development of the nephrons however, continue through to week 32-36 of gestation.[9]


Fetal Development

There are a number of factors that occur in regards to the kidneys during the fetal period of development, the most important of which is the continued generation of nephrons. There are specific genes expressed for the continued nephrogenesis, with vasculature created to supply the newly formed kidneys. There are certain events that occur for the kidneys to achieve their correct anatomical position before they are fully formed, as well as further maturation of the glomeruli post-natally before the kidneys are fully functional.


Nephrogenesis

The formation of nephrons continues well after the embryonic period in concert with the branching of the ureteric bud [10], ending between week 32-36 of gestation [11]. It is during this period that the self-renewing process of the progenitor cells ceases and they differentiate into nephrons for the final time [12]. The process of nephron formation is shown in the second diagram to the right [13].

(A) The mesenchymal cells interact with the ureteric bud, causing branching of this structure to occur (B). Renal vesicles are also formed at these branch points which then fuse to the ureteric stalk (C), creating S-shaped bodies. (D) Glomerular development occurs as this structure continues to develop, forming a nephron.

Although nephrogenesis is terminated by week 36, the resulting kidney is not yet fully functional. At birth, although the infant’s kidneys are developed enough to maintain homeostasis and are sufficient for growth and development, their functional capabilities are decreased. This is a result of the transition from depending on the placenta to maintain homeostasis of fluid and electrolyte balance while in-utero, to maturation of the neonatal glomeruli once born [14]. This maturation phase due to postnatal adaption to extrauterine life occurs during early infancy [15].

While it is not well known the mechanisms by which nephron number is determined, the causes of several disorders and diseases, such as renal disease and hypertension, have been attributed to a low nephron count [16]. It has been determined that a decrease in the number of progenitor cells, a possible result of genetic abnormalities, toxic insults, and nutritional deficiencies [17], can result in fewer branching of the ureteric buds, leading to impaired kidney growth [18]. Therefore, nephron number is important as it can show the success/extent of nephrogenesis, and thus be used to determine if any and what genes and environmental factors may aid this process [19].


Genes

While there are many genes and transcription factors that regulate the formation of early kidney development, the main factor that continues to be expressed as the fetal kidney develops is the Gremlin gene. The gene, coded GREM1, has been found to play a key role in the formation of the kidneys and nephrogenesis in general. When the kidney is fully formed, the expression of this gene is relatively low in an adult. However, it is thought that many renal diseases and their progressions are linked to an overexpression of this gremlin gene [20].

The morphology of the kidney when Gremlin is expressed at normal levels (left), compared to when the gene is over-expressed (right).


Anatomical Position

The kidneys initially begin to develop proximally to the pelvis, located at the level of the upper sacral segments. In order to attain the correct anatomical position, as the fetus develops, they continuously become more cranial in position until they reach the dorsal sides of the body at around the T12~L3 levels. This process is usually completed by week 9 of fetal development and occurs as a result of the kidneys coming into contact with the supra-adrenal glands, as well as due to the growth of the embryo’s body and abdominal cavity. These organs are medially rotated by up to ninety degrees during their ‘ascension’, so that the renal pelvis will lie on their medial aspect (Keeling & Khong, 2007; Moore, 2011).

During the entire process of anatomical positioning, the kidneys receive a bloody supply from arteries branching off at various points of the abdominal aorta. While they are initially vascularized by the lateral sacral branches of the aorta, during the ascent, they continue to receive blood at progressively higher levels. When the kidneys have achieved their correct position, they are supplied by the renal artery at the level of the 2nd lumbar vertebrae. The simultaneous rise of the vasculature helps to contribute to the ascending of the fetal kidneys (Keeling & Khong, 2007).

kidney ascent diagram

Keeling, J.W. & Khong, T.Y. (2007). The Urinary System, Fetal and Neonatal Pathology. London: Springer. 4th Ed, pp. 623

Moore: the developing human 9th edition. Saunders 2011. An imprint of Elsevier


Renin Production

While the kidneys develop, particularly the tubules, the production of renin can be found within these areas. As the tubular activity increases and this component proliferates in number and size, it is noted that growth is proportional to the amount of renin produced; as growth and functional state of the tubules increase, so does the concentration of renin created [21].

Urethra

The urethra is a structure that allows for excretion of urine, and presents as a tube from the urinary bladder to the external urethral orifice. The urethra originally develops from the cloaca during fetal development. The cloaca can be divided into the anorectal canal (dorsally) and the urogential sinus (ventrally). The bladder develops from the superior portion of this urogenital sinus (endoderm), and the inferior portion develops into the urethra. The endoderm of the urogenital sinus derives the urethral epithelium, and the splanchnic mesenchyme develop into the connective tissue and smooth muscle components of the urethra.[22]

Urethra-bladder.jpg

The anterior part of the urogenital sinus (develops into the bladder) has an opening at the apex which is connected to the allantois during fetal development. The function of this opening at the apex of the fetal bladder is to drain the developing bladder to the allantois via the umbilical cord. At around week 15 of fetal life, the allantois regresses and becomes known as the urachus; at which time the vesicourethral canal develops into the pelvic segment of the urethra in the male fetus, and the entire urethra in the female fetus. The remaining parts of the urogenital sinus (posterior portion) "later develops into the phallic urethra in the male and the lower portion of the vagina and vaginal vestibule with perineal urethra orifice in the female." (Hila Milo Rasouly, Weining Lu. 2013) [23]

The urethral sphincter complex is important in controlling urination frequency and timing, and is histologically identifiable within the urogenital sinus from week 9 of development as a mesenchymal condensation after the cloacal division. It develops into an inner layer of smooth muscle fibres and outer layer of striated muscle layers by week 15 of development, which further develop into an omega shaped muscle apparatus surrounding the urethra. The urethral sphincter complex muscles are innervated by autonomic and somatic nervous systems, and correct development of the muscle nerve innervation and the urethral sphincters are essential in the maintenance of normal urinary continence post natally. [24] External urethral sphincters are thought to develop within week 10 of development. [25]

Ureter

The development of the ureter typically begins during week 4 of gestation. The process begins from the ureteric bud, which arises from the caudal region of the mesonephric ducts (also known as Wolffian ducts) that run along the edge of the intermediate mesoderm and grows into the adjacent metanephric mesenchyme resulting in the formation of the metanephros and its collecting system [26]

<pubmed>23123402</pubmed> <pubmed>23408557</pubmed> <pubmed>24439109</pubmed>

Duplicated Ureter

<pubmed>24469670</pubmed> <pubmed>25010444</pubmed>

Bladder

The role of the urinary balder in the renal system is to store urine produced by the kidneys before it is excreted via the urethra [27]. A flexible epithelium is essential for the bladder as it changes volume by contracting and relaxing depending on the volume of urine in the body. A fusion event occurs between the common urogenital sinus and the mesonephric duct, this divides the rectal components from the urine components and it allows the bladder to develop.

The urinary bladder develops in the first 12 weeks of gestation from the urogenital sinus and the surrounding splanchnic mesenchyme, these development events are controlled by complex epithelial–mesenchymal signals. The vesical part of the urogenital sinus is attached to the allantois and goes on to form the bladder [28]. The lamina propria, the muscle coat and the adventitia all develop from the splanchmic mesoderm whilst the epithelial lining is derived from the endoderm of the urogenital sinus [29].

Initially the epithelium lining of the urinary bladder is made from two distinct cell layers, the superficial layer and the basal layer. Up to week 11 the rest of the balder wall consists of mesenchyme that gradually matures into lose connective tissue. At the 13th week collagen begins to appear, by the 14th week it is abundant in the lamina propria and by week 15 it has extended into the superficial muscle bundles. Smooth muscle cells begin to appear in the connective tissue during week 12, they initially appear in the proximal part of the organ but they spread distally over time. At 21 weeks the epithelium is 3-4 layers thick, the superficial layer, the intermediate layer, lamina propria and the basal lamina. This epithelium is specialised and contains features that are characteristic of urothelial differentiation so that urine is unable to pass through the bladder wall [29].

The muscular coat of the bladder does not develop until after the kidneys have begun to produce urine this is not a problem for the embryo as urine is released directly into the amniotic cavity [29]. The muscles in the bladder however are very important for normal urine output once the foetus have been delivered; as development continues the walls of the bladder muscle thicken and there is a decrease in collagen content, this increases the compliance of the bladder [29].

During development the bladder only produces immature reflexes rather than the voluntary bladder control that is only seen once the infant is toilet trained. It is suggested that the switch between involuntary reflexes and voluntary contractions is due to the development of the central and peripheral neural pathways that control the contraction of the bladder [30].It also could be due to the increasing number of nerves in the detrusor muscle during foetal development, this would lead to an increase control over the bladder wall due to the increase in nerves present [27].

Abnormalities

MRI showing renal agenesis

Renal agenesis

Renal agenesis is a congenital abnormality referring to the failure of the development of the kidneys and ureter produced by a lack of interaction between the ureteric bud and the metanephric mesenchyme. Renal agenesis can occur in two forms, infants can be born with either bilateral or unilateral renal agenesis. Infants born with bilateral renal agenesis are incompatible with life and are born usually stillborn, or die within a few days after birth [31]. Unilateral renal agenesis has a frequency of 1 in 5,000 newborns, in contrast to bilateral renal agenesis the rarer of the two, occurring in 1 in 30,000 infants [32].

Induction of the ureteric bud from the nephric duct is mediated by glia cell-derived neurotrophic factor (GDNF), which is secreted by the metanephric mesenchyme and interacts with the tyrosine kinase c-Ret receptor expressed in the ureteric bud in order to induce branching of the nephric duct [31] In animal models, renal agenesis is linked to signalling failures failure of the GDNF–RET signalling [33]. A complex molecular network that includes regulation by EYA1, the sine oculis homeobox homologues SIX1 and SIX4, and PAX2, controls the activation of GDNF in the metanephric mesenchyme. In addition, members of the HOX11 paralogous genes13 and the signalling molecule growth and differentiation factor 11 (GDF11) 14 are required for GDNF signals that are derived from sources other than the metanephric mesenchyme (for example, the developing gut) are not interpreted in more rostral parts of the embryo. Although Mutations in GDNF or RET have yet to be linked with mutations in patients with kidney defects such as renal agenesis. A possible explanation for this could be because human kidney development is not susceptible to the slight reduction in protein level that results from heterozygous inactivation. [32]

Renal agenesis is typically associated with other congenital defects, including:

  • Oligohydraminos
  • Facial abnormalities including: wide set eyes, a recessed chin and low-set ears

<pubmed>20798957</pubmed> <pubmed>24439109</pubmed> <pubmed>18252215</pubmed>

Polycystic Kidney Disease

Cyst formation at the level of the cell, nephron, and kidney

Polycystic kidney disease (PKD) is a common genetic disorder characterized by the formation of fluid filled cysts in the kidneys, which displace normal renal tubules. There are two types of PKD, autosomal dominant polycystic kidney disease (ADPKD) and autosomal recessive polycystic kidney disease (ARPKD).

PKD affects approximately 1 in 1000 individuals, with ADPKD accounting for the majority of the cases reported[34] [31]. ADPKD, also known as adult-onset polycystic kidney disease is commonly reported to present in adulthood in association with hypertension and renal failure [35]. The disease is linked to the mutations in the genes encoding polycystin-1 (PC1) and polycystin-2 (PC2), which is characterized by perturbations of renal epithelial cell growth control, fluid transport, and morphogenesis [34]. These mutations ultimately affect multiple signaling pathways, which cause aberrant gene transcription, cell proliferation, and ion secretion, which in turn result in the formation of benign fluid-filled cysts. As cysts balloon out from individual nephrons, their collective effect leads to the displacement of the normal renal parenchyma and the formation of a cyst-filled kidney with reduced functional capacity [34]. In ADPKD, the growth of renal cysts produces a progressive increase in renal volume and destruction of the parenchyma, leading to terminal chronic renal failure in adulthood [31].

ARPKD, however is the rarer form of PKD, affecting approximately 15% of cases. It commonly presents during the second or third trimester of fetal development. Ultrasound images show kidneys that are usually 'bright' or echogenic and are often associated with progressive oligohydramnios [35].

<pubmed>16932388</pubmed> <pubmed>17878895</pubmed> <pubmed>18728845</pubmed> <pubmed>25263802</pubmed> Mutations in SALL4, a transcription factor important in renal development, can result in renal malformations. <pubmed>21258884</pubmed> <pubmed>25211294</pubmed> <pubmed>16462154</pubmed> <pubmed>11458035</pubmed>

Horseshoe Kidney

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References

<pubmed>18631884</pubmed> <pubmed>20807610</pubmed> <pubmed>20388228</pubmed> <pubmed>11746154</pubmed> <pubmed>25036148</pubmed>

The overexpression of the gremlin gene (GREM1) has been found to be a cause of renal disease.

<pubmed>24500691</pubmed>

References

  1. Kim Ann Zimmermann (2013). “Urinary System: Facts, Functions & Diseases” Feb 11 2013
  2. Stanford (2014). “Anatomy of the urinary system”
  3. <pubmed>20388228</pubmed>
  4. <pubmed>21079243</pubmed>
  5. <pubmed>25058584</pubmed>
  6. <pubmed>24013366</pubmed>
  7. <pubmed>24855634</pubmed>
  8. <pubmed>24656820</pubmed>
  9. <pubmed>25088264</pubmed>
  10. <pubmed>24656820</pubmed>
  11. <pubmed>24488483</pubmed>
  12. <pubmed>24656820</pubmed>
  13. <pubmed>24011574</pubmed>
  14. <pubmed>24781774</pubmed>
  15. <pubmed>24623338</pubmed>
  16. <pubmed>24656820</pubmed>
  17. <pubmed>24488483</pubmed>
  18. <pubmed>24656820</pubmed>
  19. <pubmed>24022365</pubmed>
  20. <pubmed>25036148</pubmed>
  21. <pubmed>19871238</pubmed>
  22. Schoenwolf: Larsen's human embryology, 4th ed. chapter 15
  23. <pubmed>23408557</pubmed>
  24. <pubmed>23408557</pubmed>
  25. Ludwikowski B, Oesch Hayward I, Brenner E, Fritsch H. The development of the external urethral sphincter in humans. BJU Int. 2001 Apr;87(6):565-8.
  26. <pubmed>24439109</pubmed>
  27. 27.0 27.1 <pubmed>3627353</pubmed>
  28. <pubmed>23371862</pubmed>
  29. 29.0 29.1 29.2 29.3 <pubmed>2621133</pubmed>
  30. <pubmed>22535797</pubmed>
  31. 31.0 31.1 31.2 31.3 <pubmed>23169372</pubmed>
  32. 32.0 32.1 <pubmed>17878895</pubmed>
  33. <pubmed>18252215</pubmed>
  34. 34.0 34.1 34.2 <pubmed>21079243</pubmed>
  35. 35.0 35.1 <pubmed>11746154</pubmed>