Monday, April 29, 2013

A Few More Fungi



I normally don't follow up one blog posting with another on the same topic, but my students began a slide culture of two species of fungi last week and we got to see the results in lab today. 

The procedure is pretty simple.  Students use a well (depression) slide and cover slip to make the culture.  Both slide and cover slip are dipped in ethyl alcohol and then passed through the flame of a Bunsen burner to sterilize them. 

A thin line of Petroleum jelly is applied to three sides of the depression.  Then one or two drops of melted Sabourand agar is added to the well and covered with the cover slip.  The slide is allowed to cool on its side with the non-petroleum jelly edge up.  This makes a thin reservoir of agar with an air pocket at the top.

Once the agar has solidified, the cover slip is slide down so the agar can be inoculated with the spores for the test culture.  Put the cover slip back on and place in a Petri dish containing damp filter paper (use something to keep the slide above the filter paper).  Place in an incubator at 25 degrees C for one week and then check the results.  (The procedure can be found in the Pearson microbiology lab book called Symbiosis)

This allows you to use a light microscope to see the delicate structures of the fungi without disturbing them.

The first set of images are Saccharomyces cerevisiae - yeast.

Living yeast cells at 400x taken with a Leica microscope with a digital camera attached.  The red arrows show budding, an asexual process in which the parent cell copies it nucleus and then the bud, or daughter cell, grows out of the side of the parent cell. 

Living yeast cells at 1000x (oil immersion).  A closer look at some buds.  Notice the nuclei of the cells.

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The second set of images are of Penicillium chrysogenum (AKA P. notatum).  Penicillium is an ascomycota.


This first image, taken at 1000x with immersion oil, shows a germinating conidia spore. 
 

Penicillium at 400x.  This one is a bit farther along and includes a conidiophore and conidia.
 
Living hyphae at 400x.  You can clearly see that Penicillium is a septate fungus - the individual cells are separated by cross walls called septa.

Living hyphae at 1000x (oil immersion).  This is a closer look at some of the the septa that separate the cells of the hyphae.

 A conidiophore and conidia at 1000x (oil immersion). 
 
Adding a digital camera to the instructor's microscope in a microbiology class has been wonderful.  When I was but a wee laddy back in my high school and college biology classes, digital technology hadn't been invented.  (Yes, I am old.) It it amazing to be able to show my students live images of samples in lab and to be able to capture those images.
 
With a steady hand and some patience, you can take an image directly through the eyepiece of a microscope with any smart phone or digital camera.( If you are a teacher, just tell your students it can be done and they will have it figured out in about 2 minutes.)  In my lab I built a camera mount out of a tripod and old mechanical stage which lets me easily position the camera and keep it in place.  This is especially useful on a binocular scope where you can dedicate one eyepiece to the camera. 
 
Feel free to link to out blog.  Our Creative Commons licence allows you to copy, use, and modify any image just as long as you give credit to Eastfield College don't use images for commercial purposes.
Creative Commons License
 Murry Gans
Microscopy Lab Coordinator
Eastfield College
Mesquite, TX
 
 
 

 





Wednesday, April 24, 2013

Fungi - Images for Eastfield College Microbiology



This semester I got the chance to teach a microbiology class here at Eastfield College.  In lab we are studying fungi so, having some pretty cool microscopes at my disposal, I did some imaging for my class.  So this blog will be slightly different since it is intended for my students, but it still has some pretty cool images - even if you aren't in my micro class.

In general, fungi are eukaryotic, unicellular or multicellular, heterotrophic, and have cell walls composed of chitin.  (Chitin is also in the exoskeletons of insects and is what goes "crunch" when you step on a bug.  The cell walls in plants are composed of cellulose and those in bacteria are composed of peptidoglycan - great test questions, by the way.)

There are lots of different types of fungi and they are everywhere.  Watch any local weather report when they do the "pollen count", you will always see fungi. Rag weed may come and go with the season, but fungal spores are always present.

It is really kind of silly to include fungi in a "pollen count" since fungal spores aren't pollen.  Pollen is the male gametophyte of plants and ultimately will result in the formation of two sperm cells that will fertilize the egg and the polar nuclei of the ovule to produce the embryo and the endosperm.  Fungal spores are haploid cells that are produced by meiosis and are used to disperse the fungus.  When they land in a suitable location they germinate and grow.

Yeast - Saccharomyces cerevisiae

The image below was taken by Dr. Tammy Oliver using a Leica microscope with a digital camera attached.  This prepared slide shows the general morphology of yeast cells.  The original magnification on this image is 1000x using oil immersion. 




 A prepared slide showing asexual budding.  1000x (oil). 


Aspergillus

According to our lab manual, Aspergillus is a Deuteromycota, which means that no sexual reproductive phase as yet been discovered.  Of course, that doesn't mean that it doesn't reproduce sexually, just that no one has seen it.  (Maybe it is shy.)

Aspergillus reproduces asexually by forming conidia (conidium, singular) on conidiaphores.  In our prepared slides the conidia are grouped in what appears to be a sporangium, but it isn't, so be careful.

Hyphae are composed of cells that are connected together, end to end.  They may be separated from each other by internal cross walls, in which case they are called septate hyphae.  If they don't have cross walls they are aseptate hyphae.  Even if they have cross walls, those cross walls are very porous allowing the sharing or cytoplasm and organelles, including nuclei.  In essense, the hyphae are long continuous cells with multiple nuclei.  This condition is called a syncytium.

In the image below you can see the mass of hyphae that make up the mycelium, or body of the fungus.  I have also indicated a conidiophore - the filament that holds up the structures that make the conidia spores.  Raising the spores up above the mycelium helps them spread.



The image below shows the conidia and the conidiophore.


Dr. Tammy Oliver made the image below from a prepared slide.  In this image you can see the conidia and some of the detail of the underlying structures. 


Here is a closer look.


 
Eastfield has two scanning electron microscopes.  We took the smaller, table top SEM into the microbiology lab today to allow the students to see it in action.  The images of Aspergillus were taken during lab using a Hitachi TM-1000 SEM.
 

 Aspergillus conidiophore and conidia.  [500x]
 
Hitachi S-3400N [200x]
 
 Hitachi S-3400N [440x]
 
 Hitachi S-3400N [750x]


Conidia [2,010x]



 Conidia spores [1,200x]  Image made during lab.
 
 
 Conidia spores [6,000x]
'
 

One of the cool things about SEMs is that you can make calibrated measurements directly on the image.  On the image above you can see that these fungal spores are about 4 microns in diameter.
 

Rhizopus nigricans


Some time ago I brought a piece of moldy bread into the lab for imaging.  This was a specialty bread baked by my local grocery store which meant it didn't have any preservatives added.  It molded beautifully.

First let's take a look at images made with the digital dissecting scope.

Most people think of moldy bread as pretty disgusting, but once you see it under a microscope the colors and structures are pretty amazing.  Unfortunately, I don't have the luxury of a prepared slide to tell me what I am seeing, but I am pretty sure the the black sporangia (spore-forming bodies) are black break mold - Rhizopus nigricans  and the white mold in the middle with green under it is Penicillium.

 



 Sporangia of Rhizopus nigricans



Green and white mold of Penicillium
 
 Notice the edge of the white mold just below the yellow  You can begin to make out the conidia and  conidiaphores of Penicillium.

 In the center of the image you can clearly see the white, branching conidiaphores of Penicillium.
 
 

 More white conidiophores (I seem to be obsessed!!)
 
 
Conidia and conidiaphores on moldy bread.  The pebbly substrate is bread!  [500x]
 
 Conidiaphore and conidia [2,010x]


 [1,200x]


 
To make the images below I cut a cross section through the moldy slice of bread.  In fact, you can see the voids caused by the production of carbon dioxide during fermentation.  The bread is to the left with the mycelium of the fungus above.

 
Bread and mold [73x]
 

 Bread on bottom left corner.  Hyphae and mycelia above. [200x]

 Sporangia and sporangiophores of Rhizopus [27x]

 
Sporangia and sporangiophores [50x]
 

 The funciton of sporangiophores is to get the sporangia up above the surface of the bread so the spores can spread more easily.  [50x]



 
 [250x]
 
Zygospores [2,010 x]
 

Basidomycota - the mushrooms

These first images were made by a student on the table top SEM.
 
This image shows a gill from under the cap of the mushroom.  You can clearly see that the basidiospores occur in groups of 4.  They extend from a club-shaped basidia which give this groups its name. [200x]
 
 

 Basidiospores in groups of 4  [800x]
 

From a prepared slide - a cross section through the stalk and gills of a Coprinus mushroom.

 Prepared slide.  Original magnification 1,000x (oil)
 

  
Prepared slide.  Detail showing basidium and basidiospores.  Original magnification 1000x (oil)
 
WOW.  That is a lot of fungi and hopefully the images are interesting and will be useful to my students.  This is the first time that I have included images from 4 different microscopes - the TM-1000 SEM, the S-3400N SEM, a digital dissecting scope, and a digital light microscope, which I think is pretty neat.
 
As always, I would appreciate any feedback on the blog.
 
Eastfield College Microscopy Lab
Eastfield College
Mesquite, TX